Bats are a highly diverse mammal species with a dense virome and fascinating immune system. The following project utilizes metagenomics in order to identify DNA viruses present in populations of silver-haired bats and Mexican free-tailed bats from southern Arizona. A significant number of DNA viruses and novel viruses were identified in the Cressdnaviricota phylum and Microvirdae family.

Animal shelters can be stress-inducing environments for dogs because of the noise, social isolation and unpredictable housing (Hennessy et al., 2020). Dog enthusiasts and researchers alike have found that social interaction can help alleviate stress in dogs. The aim of this study was to understand dogs’ interaction preferences to improve their welfare in animal shelters. We hypothesized that there would be statistically significant differences between both the time dogs spent in dog-dog and dog-human interactions. The dogs’ interaction preferences were operationalized as the percentage of their play time they spent in dog-dog, dog-human and dog-environment interactions. A total of twelve dogs from the Animal Humane Society (AHS) in Golden Valley, Minnesota shelter participated as subjects in the study. The study ran for two weeks, and there were 2 sessions of 15 minute playgroups recorded at 9:00 AM, 11:40 AM and 2:20 PM. Each playgroup consisted of two to four dogs. We found statistically significant differences between the percentage of each dog’s individual time they spent in dog-human interactions, which is supported by the literature. Differences between the percentage of each dog’s time in dog-dog interactions were nearly, but not quite statistically significant. Further research is needed to determine if age, size and breed contribute to the dog’s interaction preferences. More research is also needed to determine whether individual differences in preference for dog-dog interaction exist between dogs, and how this knowledge can be applied to improve dogs’ welfare in shelters. Our research suggests that shelters should continue to provide dogs with play time to interact with humans, as it is helpful in alleviating the impact of environmental stressors.

Type 1 diabetes is a metabolic disorder in which the pancreas produces little to no insulin due to the cells being destroyed by a person’s own body. A potential treatment for this disorder is the allogeneic transplantation of pancreatic beta cells. Unfortunately, this potential solution requires the use of immunosuppressants. For my project with the Weaver Lab, I will be assessing pseudoislet survival in macroencapsulation via injection molding. I will be analyzing survival and metabolic assays of the pseudoislets in the mold process. Pseudoislets in hydrogels usually undergo hypoxia-included cell death due to the diffusion distances oxygen has to travel. We will test the impact of macroencapsulation device geometry on hypoxia within encapsulated cells. I will be culturing pancreatic cells and encapsulating them in hydrogels. Macroencapsulation devices will be utilized to shield islets from the immune system and eliminate the need for immunosuppressants. In order to analyze the cells’ structure and to ensure their viability, confocal microscopy will be used. Staining for live cells will be done using calcein AM which produces green fluorescence and indicates live cells. Staining for dead cells on the other hand will be done using an ethidium homodimer which produces red fluorescence and indicates dead cells. To determine if the cells are metabolically active the Alamar Blue assay will be used.

Ultra-short-pulse (USP) lasers in the visible range have been shown to have widespread sterilizing effects on pathogens, which is believed to be caused by mechanical perturbations induced in the pathogen that disrupt essential processes leading to inactivation. This paper demonstrates a complete inactivation of Zika virus, a single-stranded enveloped RNA virus, using USP-laser technology and adds to the growing body of literature on the effectiveness of USP-laser inactivation. The paper also surveys previous inactivation studies to draw inferences about the nature of the Zika virus inactivation. We suggest that the method of inactivation in Zika virus is the selective amalgamation of viral capsid proteins into a nonfunctional mass of proteins because of the laser-induced vibrations, which mechanically prevents the release of viral RNA. The survey of similar inactivation experiments also supports the notion that the viral antigens might be unaffected by USP-laser inactivation, justifying the exploration of vaccine development using USP-laser inactivated Zika virus.

Industries and research utilizing genetically-engineered organisms are often subject to strict containment requirements such as physical isolation or specialized equipment to prevent an unintended escape. A relatively new field of research looks for ways to engineer intrinsic containment techniques- genetic safeguards that prevent an organism from surviving outside of specific conditions. As interest in this field has grown over the last few decades, researchers in molecular and synthetic biology have discovered many novel ways to accomplish this containment, but the current literature faces some ambiguity and overlap in the ways they describe various biocontainment methods. Additionally, the way publications report the robustness of the techniques they test is inconsistent, making it uncertain how regulators could assess the safety and efficacy of these methods if they are eventually to be used in practical, consumer applications. This project organizes and clarifies the descriptions of these techniques within an interactive flowchart, linking to definitions and references to publications on each within an Excel table. For each reference, variables such as the containment approach, testing methods, and results reported are compiled, to illustrate the varying degrees to which these techniques are tested.

Industries and research utilizing genetically-engineered organisms are often subject to strict containment requirements such as physical isolation or specialized equipment to prevent an unintended escape. A relatively new field of research looks for ways to engineer intrinsic containment techniques- genetic safeguards that prevent an organism from surviving outside of specific conditions. As interest in this field has grown over the last few decades, researchers in molecular and synthetic biology have discovered many novel ways to accomplish this containment, but the current literature faces some ambiguity and overlap in the ways they describe various biocontainment methods. Additionally, the way publications report the robustness of the techniques they test is inconsistent, making it uncertain how regulators could assess the safety and efficacy of these methods if they are eventually to be used in practical, consumer applications. This project organizes and clarifies the descriptions of these techniques within an interactive flowchart, linking to definitions and references to publications on each within an Excel table. For each reference, variables such as the containment approach, testing methods, and results reported are compiled, to illustrate the varying degrees to which these techniques are tested.