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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Examination of the Association Between In Vitro Propiconazole Sensitivity and Field Efficacy Among Five Diverse Sclerotinia homoeocarpa Populations on Turfgrass

Popko, James T, Jr. 01 January 2011 (has links) (PDF)
Sclerotinia homoeocarpa F.T. Bennett, the causal agent associated with dollar spot, is a common and economically challenging turfgrass disease in North America. Acceptable turfgrass quality requires the optimization of cultural practices and the judicious use of fungicides. Sclerotinia homoeocarpa causes significant damage to turfgrass swards from May to October annually, therefore, requiring multiple fungicide applications to maintain satisfactory turfgrass quality throughout the growing season. Sterol demethylation inhibitor (DMI) fungicides are among the most widely used in the United States and frequent use has led to the development of fungicide resistance to the DMI fungicide class. The precise mechanism of DMI fungicide resistance in S. homoeocarpa is not completely understood, however over expression of the CPY51A gene or efflux transporter genes have been reported as the molecular mechanism for other fungal systems. Fungicide resistance to the DMI class exhibits a gradual population shift towards insensitivity that can be monitored using In vitro fungicide sensitivity assays. In vitro fungicide sensitivity assays have been used to detect fungicide sensitivity differences in different S. homoeocarpa isolates and currently serve as the most accurate methodology to detect DMI insensitivity in S. homoeocarpa. Documentation of DMI field efficacy on native S. homoeocarpa populations with differing in vitro sensitivities has not been examined thoroughly and would provide critical information regarding the association between in vitro fungicide sensitivity and DMI field efficacy. The objectives of this research are (i) to determine the association between in vitro propiconazole sensitivity and reduced field efficacy for five native S. homoeocarpa populations and (ii) to develop a qualitative in vitro sensitivity assay for detection of S. homoeocarpa isolates responsible for practical field resistance.
2

In Vitro Sensitivity of Murine Fibrosarcoma Cells to Photodynamic Therapy, Ultraviolet Light, and Gamma-Rays

Roy, Deboleena 09 1900 (has links)
Photodynamic therapy (PDT) is a new form of cancer treatment that uses the localized delivery of light and a photosensitizing drug, which is selectively retained in tumor tissue, to cause photochemically induced cell death. Although PDT mediated by the sensitizer Photofrin (Ph-PDT) is currently in Phase III trials for a number of human cancers, the exact mechanism(s) involved in PDT induced cytotoxicity is not fully understood. Also, Photofrin has a number of drawbacks including extended cutaneous photosensitization and low absorption in the red region of the spectrum. This has lead to the search for improved sensitizers. In vitro, tumor cells resistant to PDT have been developed from PDT sensitive cell lines to examine the mechanism(s) of PDT action. In this work, the sensitivity of RIF-1 murine fibrosarcoma cells and RIF-1 derived Ph-PDT resistant RIF-8A cells was examined following several damaging agents including PDT mediated by the novel Ruthenium phthalocyanine photosensitizer JM2929 (JM2929-PDT), UV, gamma-radiation, and hyperthermia. Gamma-radiation sensitivity of two other RIF-1 derived Ph-PDT resistant variants, CPR-C1 and RIF-P16CL8, was also examined. RIF-8A cells showed cross resistance to UV but increased sensitivity to gamma-rays compared to RIF-1 cells. RIF-1 and RIF-8A cells showed similar sensitivity to JM2929-PDT and hyperthermia. It is possible that Ph-PDT induces a "UV -like" component of damage and/or there is some overlap in the pathways for the repair of UV and Ph-PDT induced damage, but not JM2929-PDT, hyperthermia, and ionizing radiation damage in RIF-1 and RIF-8A cells. A cross resistance to gamma-rays was observed for CPR-C1 but not RIF-P16CL8 cells. Since Ph-PDT resistant CPR-C1 cells, but not RIF-8A cells or RIF-P16CL8 cells, show a cross resistance to gamma radiation, these results suggest that the cellular changes required for RIF-8A, RIF-P16CL8, and CPR-C1 cells to become resistant to Ph-PDT are different. Survival of RIF-1 and RIF-8A cells following gamma-rays in the presence of either Photofrin or JM2929 was also examined. Results suggest sensitization of RIF-1 cells, but not RIF-8A cells, to gamma-radiation in the presence of Photofrin. Gamma-radiation in the presence of JM2929 had no sensitizing effects on the survival of RIF-1 and RIF-8A cells. DNA repair of a UV-damaged reporter gene was also examined in untreated as well as Ph-PDT, JM2929-PDT, UV, cisplatin, and hyperthermia pretreated RIF-1 and RIF-8A cells. Results suggest an increased repair of UV damaged DNA in untreated RIF-1 cells compared to untreated RIF-8A cells. Ph-PDT, JM2929-PDT, and UV pretreatments resulted in an increased reactivation of a UV damaged reporter gene in RIF-1 cells compared to RIF-8A cells. Enhanced reactivation of a UV damaged reporter gene was not observed in either RIF-1 or RIF-8A cells following cisplatin or hyperthermia pretreatment. Enhanced expression of an undamaged reporter gene was greater in RIF-8A cells compared to RIF-1 cells following Ph-PDT pretreatment, but similar to RIF-1 cells following pretreatment with all other agents. These results suggest that the relation between survival, DNA repair of an actively transcribed gene, and transcriptional enhancement of an actively transcribed gene, varies in RIF-1 and RIF-8A cells depending on the damaging agent used. However, decreased reactivation of a UV damaged reporter gene in RIF-8A cells may be related to Ph-PDT and UV resistance seen in RIF-8A cells. / Thesis / Master of Science (MSc)
3

Age-Related Differences in In-vitro Sensitivity to Inhibition of Human Red Blood Cell Acetylcholinesterase and Plasma Butyrylcholinesterase by the Cholinesterase Inhibitors Physostigmine (PHYS), Pyridostigmine (PYR), Donepezil (DON) and Galantamine (GAL)

Lee, David 31 July 2009 (has links)
Alzheimer’s disease (AD) is a chronic, progressive neurodegenerative disorder, characterized clinically by a progressive loss of memory, cognitive function, ability to care for oneself and psychiatric symptoms. First-line agents for the treatment of AD are ChE inhibitors (DON, GAL), whose modest clinical efficacy and the high incidence of dose-limiting toxicities limit their clinical utility. In addition to AD, ChE inhibitors (PYR) are used for other medical conditions, such as myasthenia gravis (MG). Furthermore, ChE inhibitors (PYR) are used by military personnel prophylactically if impending exposure to chemical warfare agents, e.g., soman, is suspected. The purpose of this research project was to understand the effect of age on the in-vitro sensitivity of ChE inhibitors in human RBCs and plasma. Understanding possible covariates, such as age and gender, may assist in optimizing dosing regimens of ChE inhibitors and/or developing newer ChE inhibitors with better adverse effect profiles. Plasma PHYS concentrations were measured by a validated HPLC-FD method. RBC AChE activity and plasma BuChE activity were measured by a modified Ellman’s colorimetric method using the model substrates, acetylthiocholine and butyrylthiocholine, respectively. The kinetics of RBC and plasma ChE activity followed Michaelis-Menten kinetics. Acetylthiocholine was found to be a nonselective substrate (RBC AChE Km = 73 μM; plasma BuChE Km = 117 μM); while butyrylthiocholine was a selective substrate for plasma BuChE (RBC AChE Km = 130,000 μM; plasma BuChE Km = 72 μM). For the following studies, RBC AChE activity was measured using acetylthiocholine as the substrate and plasma BuChE activity was measured using butyrylthiocholine as the substrate. This research project was performed in two parts: First, mechanistic studies of PHYS, PYR, DON and GAL, explored and determined the mechanism of in-vitro inhibition of RBC AChE and plasma BuChE inhibition, as well as the in-vitro degradation of PHYS in human whole blood, plasma and RBC. PHYS was rapidly degraded in human whole blood, RBC and plasma and followed Michaelis-Menten kinetics but its degradation clearance - scaled to whole blood clearance - was only predicted to account for 4-6% (i.e., 195-261 ml/min) of the reported total body clearance for PHYS (4500 ml/min). RBCs were responsible for 60% of the whole blood clearance while plasma accounted for 40% of the whole blood clearance. Inhibition results indicated that both PHYS and PYR were nonselective and rapid suicide ChE inactivators. PYR inactivated RBC AChE more rapidly at low concentrations and inactivated plasma BuChE more rapidly at high concentrations, but inactivated both more rapidly than PHYS. PHYS was a more potent inactivator than PYR with a Ki for RBC AChE of 0.011 μM and 0.063 μM, respectively, and 0.023 μM and 0.036 μM, respectively for plasma BuChE. DON was found to be a noncompetitive inhibitor for RBC AChE (Ki,noncomp = 114 μM), but a competitive inhibitor for plasma BuChE (Ki,comp = 213 μM). GAL was found to be a competitive inhibitor for both RBC AChE (Ki,comp = 66 μM) and plasma BuChE (Ki,comp = 358 μM). The second part involved a clinical study with ten young and nine elderly healthy subjects, balanced for gender, who donated blood for an in-vitro study in order to assess any age- and gender-related differences in in-vitro sensitivity to RBC AChE and plasma BuChE inhibition to all four ChE inhibitors. Elderly adults were found to be 2-3-fold less sensitive compared to the young adults for PHYS (BuChE Ki,pss; 0.010 and 0.015 μM, young and elderly, respectively) and PYR (AChE Ki,pss; 0.12 and 0.25 μM, young and elderly, respectively) only, while neither DON nor GAL showed any age-related differences in sensitivity. The observed differences for PHYS and PYR may be due to kinetic differences in ChE inactivation between young and aged adults, rather then a difference in binding affinities/potencies. These carbamate ChE inhibitors, presumably, have a slower decarbamoylation rate in younger adults than elderly adults, which leads to the observed difference in in-vitro sensitivity. The above in-vitro results were consistent with results of a meta-analysis: In a study by Knapp et al. (1991), young males (n=6), receiving 18 mg, 24 mg and 30 mg PHYS tablets, showed similar ex-vivo plasma BuChE sensitivity to (28 %/(ng/ml)) as the in-vitro sensitivity for young males in the current study (33 %/(ng/ml)). On the other hand, in the study by Men (2004), elderly males (n=8) and females (n=8), receiving 6.7 μg/kg PHYS as 30-minute infusion, showed similar ex-vivo RBC AChE sensitivity (12 %/(ng/ml)) as the in-vitro sensitivity for elderly subjects in the current study (9.7 %/(ng/ml)). This suggests that in-vitro measurement of ChE sensitivity is predictive of ex-vivo sensitivity in clinical studies. The study results suggest that elderly adults may require a 2-3-fold higher blood concentration than young adults to achieve the same ChE inhibition. This may explain why for epistigmine, an investigational carbamate ChE inhibitor for the treatment of AD, the maximum tolerated dose observed in young adults (40 mg single dose) was lower than for older adults (90 mg/day). Higher sensitivity in young adults prevented further dose escalation, while all elderly subjects tolerated higher doses. This research may have implications for other diseases and conditions, most notably MG and as a prophylaxis of nerve gases poisoning. As patients with MG age, they may become less sensitive to PYR, the most common symptomatic treatment for MG, and an increase in dose may be required. Further, older military personnel assigned to receive PYR, may require increased doses to achieve the targeted 10% RBC AChE inhibition, necessary to protect against nerve gas poisoning.

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