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Browsing by Author "Barnard, April L."
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Item Genetic Determinants of Coxsackievirus B3 Pathogenesis(2020-10) Barnard, April L.; Robinson, Christopher M.; Evans-Molina, Carmella; Yu, AndyEnteric viruses are among the most common infectious human viruses worldwide, causing an estimated 10-15 million infections per year in the United States. Among enteric viruses, Coxsackievirus is commonly isolated and can lead to the development of meningitis, encephalitis, pancreatitis, and hepatitis. Furthermore, Coxsackievirus B3 is the primary cause of viral myocarditis and can lead to pleurodynia, with nearly 40,000 symptomatic cases reported in the United States each year. The enteroviral ssRNA genome contains a 5’ untranslated region (5’UTR) which consists of two structural components, the cloverleaf and the internal ribosome entry site (IRES), both shown to be integral to viral success. Additionally, the viral genome encodes four structural VP proteins as well as 11 non-structural proteins. Polymorphisms found within the CVB3 population have been linked to viral virulence. Here, we compare two CVB3 Nancy variants to elucidate the downstream effects observed in response to mutations found in the CVB3 genome. Implementing our novel oral inoculation model, we aimed to determine the impact mutations found in the 5’UTR and VP regions exert on viral pathogenesis. We also aimed to delineate the in vitro effects of the observed mutations. We investigated the role mutations found in the structural regions played in virus host cell attachment, in vitro cell viability, and replication. Our work has further confirmed the relevance and impact of mutations found in the VP region of the CVB3 genome.Item Regulation of myocardial oxygen delivery in response to graded reductions in hematocrit: Role of K+ channels(Springer, 2017-11) Kiel, Alexander M.; Goodwill, Adam G.; Noblet, Jillian N.; Barnard, April L.; Sassoon, Daniel J.; Tune, Johnathan D.; Cellular and Integrative Physiology, School of MedicineThis study was designed to identify mechanisms responsible for coronary vasodilation in response to progressive decreases in hematocrit. Isovolemic hemodilution was produced in open-chest, anesthetized swine via concurrent removal of 500 ml of arterial blood and the addition of 500 ml of 37 °C saline or synthetic plasma expander (Hespan, 6% hetastarch in 0.9% sodium chloride). Progressive hemodilution with Hespan resulted in an increase in coronary flow from 0.39 ± 0.05 to 1.63 ± 0.16 ml/min/g (P < 0.001) as hematocrit was reduced from 32 ± 1 to 10 ± 1% (P < 0.001). Overall, coronary flow corresponded with the level of myocardial oxygen consumption, was dependent on arterial pressures ≥ ~ 60 mmHg, and occurred with little/no change in coronary venous PO2. Anemic coronary vasodilation was unaffected by the inhibition of nitric oxide synthase (l-NAME: 25 mg/kg iv; P = 0.92) or voltage-dependent K+ (K V) channels (4-aminopyridine: 0.3 mg/kg iv; P = 0.52). However, administration of the K ATP channel antagonist (glibenclamide: 3.6 mg/kg iv) resulted in an ~ 40% decrease in coronary blood flow (P < 0.001) as hematocrit was reduced to ~ 10%. These reductions in coronary blood flow corresponded with significant reductions in myocardial oxygen delivery at baseline and throughout isovolemic anemia (P < 0.001). These data indicate that vasodilator factors produced in response to isovolemic hemodilution converge on vascular smooth muscle glibenclamide-sensitive (K ATP) channels to maintain myocardial oxygen delivery and that this response is not dependent on endothelial-derived nitric oxide production or pathways that mediate dilation via K V channels.