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- Genre: Academic theses
Description
The continued rise of temperatures and extreme heat events globally is contributing to increases in mortality and morbidity in every region of the world. Urban areas are experiencing the combined effects of anthropogenic climate change and the urban heat island effect, exacerbating the risks associated with heat for urban residents. In response, cities must make every effort to adapt, pursuing engagement in high-quality planning processes and implementing robust sets of strategies to mitigate and manage the heat. Cities are shaped by networks of plans, however, the process of systematically evaluating these plans has focused on individual plans or plan types when assessing their quality. This study combines qualitative plan quality evaluation and semi-structured interviews to assess how Vienna’s network of plans addresses heat. Two clear divides emerge when analyzing the plan network; direction-setting principles are included more often than others, and mitigation strategies are more prevalent than management strategies. These results, which are consistent across the broader plan quality evaluation literature, illuminate a clear path for Vienna to continuously improve their planning process and effectively respond to heat.
ContributorsLeyba, Bryan (Author) / Meerow, Sara (Thesis advisor) / Damyanovic, Doris (Committee member) / Hondula, David (Committee member) / Arizona State University (Publisher)
Created2023
Description
The emergence of invasive non-Typhoidal Salmonella (iNTS) infections belonging to sequence type (ST) 313 are associated with severe bacteremia and high mortality in sub-Saharan Africa. Distinct features of ST313 strains include resistance to multiple antibiotics, extensive genomic degradation, and atypical clinical diagnosis including bloodstream infections, respiratory symptoms, and fever. Herein, I report the use of dynamic bioreactor technology to profile the impact of physiological fluid shear levels on the pathogenesis-related responses of ST313 pathovar, 5579. I show that culture of 5579 under these conditions induces profoundly different pathogenesis-related phenotypes than those normally observed when cultures are grown conventionally. Surprisingly, in response to physiological fluid shear, 5579 exhibited positive swimming motility, which was unexpected, since this strain was initially thought to be non-motile. Moreover, fluid shear altered the resistance of 5579 to acid, oxidative and bile stress, as well as its ability to colonize human colonic epithelial cells. This work leverages from and advances studies over the past 16 years in the Nickerson lab, which are at the forefront of bacterial mechanosensation and further demonstrates that bacterial pathogens are “hardwired” to respond to the force of fluid shear in ways that are not observed during conventional culture, and stresses the importance of mimicking the dynamic physical force microenvironment when studying host-pathogen interactions. The results from this study lay the foundation for future work to determine the underlying mechanisms operative in 5579 that are responsible for these phenotypic observations.
ContributorsCastro, Christian (Author) / Nickerson, Cheryl A. (Thesis advisor) / Ott, C. Mark (Committee member) / Roland, Kenneth (Committee member) / Barrila, Jennifer (Committee member) / Arizona State University (Publisher)
Created2016