Further refinements and a new efficient solution of a novel model for predicting indoor climate

Lombard, Christoffel

13 June 2013

In the first two chapters of this thesis, the novel method, developed by Mathews and Richards1, for predicting the thermal performance of buildings is introduced. The further enhancement and theoretical clarification of this method is the objective of this thesis. The method is based on a very simple thermo-flow network which models only the most important aspects of heat-flow in buildings. While Mathews and Richards based their network on analysis of the primary aspects of heat-flow in buildings, this thesis derives the simplified model by reduction from a comprehensive model. In this way, the assumptions and limitations is illuminated and the theoretical foundation of the method can be established. As a result of the investigation, a new simplified model with certain theoretical benefits is suggested. In later chapters, the method is extended and refined. Also, a new calculation procedure for finding solutions of the model is presented. In particular the method is extended to include multi-zone heat-flow, structural storage- and variable thermal systems. The new solution method is powerful, simple and efficient. This thesis contributes to the establishment of a viable tool for thermal analysis of buildings. / Dissertation (MEng)--University of Pretoria, 1990. / Mechanical and Aeronautical Engineering / unrestricted

Novel model

Thermo-flow network

Mathews and richards

Multi-zone heat-flow

UCTD

Pathogenesis and Cross-species Infection of Hepatitis E Virus

Yugo, Danielle Marie

18 January 2019

Hepatitis E Virus (HEV), the causative agent of hepatitis E, is a zoonotic pathogen of worldwide significance. The genus Orthohepevirus A of the family Hepeviridae includes all mammalian strains of HEV and consists of 8 recognized genotypes. Genotypes 1 and 2 HEVs only infect humans and genotypes 3 and 4 infect humans and several other animal species including pigs and rabbits. An ever-expanding host range of genetically-diversified strains of HEV now include bat, fish, rat, ferret, moose, wild boar, mongoose, deer, and camel. Additionally, the ruminant species goats, sheep, and cattle have been implicated as potential reservoirs as well. My dissertation research investigates a novel animal model for HEV, examines the immune dynamics during acute infection, and evaluates the possibility of additional animal reservoirs of HEV. The first project established an immunoglobulin (Ig) heavy chain knock-out JH (-/-) gnotobiotic piglet model that mimics the course of acute HEV infection observed in humans and evaluated the pathogenesis of HEV infection in this novel animal model. The dynamics of acute HEV infection in gnotobiotic pigs were systematically determined with a genotype 3 human strain of HEV. We also investigated the potential role of immunoglobulin heavy-chain JH in HEV pathogenesis and immune dynamics during the acute stage of virus infection. This novel gnotobiotic pig model will aid in future studies into HEV pathogenicity, an aspect which has thus far been difficult to reproduce in the available animal model systems. The objective of the second project for my PhD dissertation was to determine if cattle in the United States are infected with a bovine strain of HEV. We demonstrated serological evidence of an HEV-related agent in cattle populations with a high level of IgG anti-HEV prevalence. We demonstrated that calves from a seropositive cattle herd seroconverted to IgG binding HEV during a prospective study. We also showed that the IgG anti-HEV present in cattle has an ability to neutralize genotype 3 human HEV in vitro. However, our exhaustive attempts to detect HEVrelated sequence from cattle in the United States failed, suggesting that one should be cautious in interpreting the IgG anti-HEV serological results in bovine and other species. Collectively, the work from my PhD dissertation delineated important mechanisms in HEV pathogenesis and established a novel animal model for future HEV research. / Ph. D. / Hepatitis E Virus (HEV), the causative agent of hepatitis E, is a zoonotic pathogen of worldwide significance. According to the World Health Organization, there are approximately 20 million HEV infections annually, which result in 3.3 million cases of acute hepatitis E and >44,000 HEV-related deaths. Hepatitis E is a self-limiting acute disease in general, but carries the ability to cause high mortality in pregnant women and chronic hepatitis in immunocompromised individuals. The underlying mechanisms of HEV host tropism and progression of disease to chronicity are unknown. My dissertation work investigates a novel animal model for HEV, evaluates the possibility of additional animal reservoirs of HEV, and examines the immune dynamics during acute infection. The first project established an immunoglobulin (Ig) heavy chain knock-out JH (-/-) gnotobiotic piglet model that mimics the course of acute HEV infection observed in humans. The dynamics of acute HEV infection were determined in both the knock-out and wild-type piglets with a genotype 3 strain of human HEV. We also investigated the potential role of immunoglobulin heavy-chain JH in HEV pathogenesis and virus infection. In the second project, we determined if cattle in the United States are infected with a bovine strain of HEV. We showed serological evidence of an HEV-related agent in cattle as well as calves born in a seropositive herd. Despite the detection of specific antibodies recognizing HEV in cattle, definitive evidence of virus infection could not be demonstrated. Our exhaustive attempts to detect HEV-related sequence from cattle in the United States failed, suggesting that one should be cautious in interpreting the IgG anti-HEV serological results in bovine and other species. Collectively, the work from my PhD dissertation research delineated important mechanisms in HEV pathogenesis and established a novel animal model for future HEV research.

Hepatitis E Virus (HEV)

gnotobiotic pig

Ig heavy-chain knock-out

novel model

animal reservoir

bovine

seroprevalence

cross-species infection