Barrett, The Honors College Thesis/Creative Project Collection

Sacred plant medicines and psychoactive compounds have been used globally throughout indigenous cultures for spiritual and medicinal purposes as early as 3500 BCE. In 1970, the United States Drug Enforcement Administration criminalized entheogens, claiming they had no medical benefit whatsoever and that they were dangerous to the population. Scientific research over the past 60 years has demonstrated the therapeutic potential of entheogens in relation to depression, anxiety, post-traumatic stress disorder, autoimmune disease, analgesia, and more. With this new research and the demonstration of entheogens' safety in clinical settings, the U.S. DEA needs to reevaluate their 50-year-old classification of entheogens. This reclassification does not necessarily designate entheogens as recreationally legal for all to use, but rather should allow for further medical research and experimentation to improve understanding of these substances' mechanisms of action and therapeutic potential for a multitude of psychiatric and physiological diseases and disorders.

As 2020 unfolded, a new headline began taking over front pages: “COVID-19”. In the months that followed, waves of fear, sorrow, isolation, and grief gripped the population in the viruses’ wake. We have all heard it, we have all felt it, indeed because we were all there. Trailing a few months behind those initial headlines, more followed that only served to breed misinformation and ludicrous theories. Even with study after study, quality, scientific data about this new virus could not come fast enough. There was somehow both too much information and also not enough. We were scrambling to process the abundance of raw numbers into some semblance of an explanation. After those first few months of the pandemic, patterns in the research are beginning to emerge. These horrific patterns tell much more than just the pathology of COVID-19. As the number of sick, surviving, and deceased patients began to accumulate, it became clear that some populations were left devastated, while others seemed unscathed. The reasons for these patterns were present long before the COVID-19 Pandemic. Disparities in health care were highlighted by the pandemic – not caused by it. The roots of these disparities lie in the five Social Determinants of Health (SDOH): (1) economic stability, (2) neighborhood and built environment, (3) education, (4) social and community context, and (5) health and health care. Minority populations, namely Black Americans, Hispanic Americans, Native Americans, and Pacific Islanders consistently have higher diagnosis rates and poorer patient outcomes compared to their White American and Asian American counterparts. This is partly because minority populations tend to have jobs that pay lower, increase exposure risk, and provide little healthcare. When unemployment increased in the wake of the pandemic, minorities were the first to lose their jobs and their health insurance. In addition, these populations tend to live in densely populated neighborhoods, where social isolation is harder. Higher poverty rates encourage work DISPROPORTIONATE EFFECTS OF COVID-19 ON MINORITY POPULATIONS 3 rather than education, often perpetuating the cycle. The recent racial history and current aggressions towards minority people might produce a social attitude against healthcare Health care itself can be expensive, hard to find, and/or tied to employment, leading to poorly controlled comorbidities, which exacerbate poor patient outcomes in the case of COVID-19 infection. The healthcare delivery system plays little part in the SDOH, instead, public policy must be called to reform in order to fix these issues.

This creative project explores the socioeconomic disparity seen amongst students in the pre-dental track along with the creation of a scholarship fund designed for need-based pre-dental students in order to cover dental school application costs. It touches on resources available for need-based students, scholarship effectiveness, as well as the service learning journals documenting the experience of researching and implementing a scholarship fund.

Our work explores a fascinating experiment in physics and science, the Double-Slit Experiment. We cover the mystery of this experiment, representing the wave and particle nature of photons, electrons, and quantum elements. We recount the history of quantum physics, an unknown field for most people due to its detachment from the world we see. Finally, we explore the capability of the human eye to detect light in its quantum state, closing the gap between us and quantum physics.

Our work explores a fascinating experiment in physics and science, the Double-Slit Experiment. We cover the mystery of this experiment, representing the wave and particle nature of photons, electrons, and quantum elements. We recount the history of quantum physics, an unknown field for most people due to its detachment from the world we see. Finally, we explore the capability of the human eye to detect light in its quantum state, closing the gap between us and quantum physics.

The 1970’s was an exciting time for those interested in avian navigation and magnetoreception. In the mid 1970’s, it had been scientifically proven that birds utilized the Earth’s magnetic fields as a means for orientation. However, while scientists now knew that birds could detect geomagnetic fields, a major question still remained: how? Several years later, physicist Klaus Schulten would bring the world much closer to an answer with the introduction of the radical pair model. With an extremely firm grasp of quantum mechanics, Schulten was able to make an amazing connection between the magnetically sensitive “radical pairs” and magnetic sensing in organisms (such as birds). The goal of this thesis is to explore this intersection of quantum mechanics and biology first illuminated by Schulten, through providing an in-depth explanation of the radical pair model itself, the quantum mechanical concepts that allow it to exist, the possible biological structures involved, and a small exploration of where the theory stands today, all to better understand the fascinating phenomenon of avian magnetoreception.