It is well established that formerly incarcerated individuals face stigma upon their return to society, negatively impacting reintegration efforts and life outcomes. Existing literature highlights the significance of stigma in influencing reentry outcomes, emphasizing gender-specific challenges faced by formerly incarcerated individuals, but fails to quantitatively study how these gender stereotypes impact public stigma. Although some research does address variations in the formerly incarcerated population and their influence on public opinion, these studies rarely focus on gender. My study directly explores how gender and stigma interact throughout reentry, by quantitatively investigating public perceptions of formerly incarcerated individuals in Washington State. I develop vignettes about hypothetical formerly incarcerated individuals that vary key facts between participants to examine the extent to which gender, offense type, and post-release behavior influence the public stigma of incarceration. Respondents are randomly assigned these vignettes to evaluate their varying perceptions, unveiling whether gender leads to differential perceptions and therefore, differential treatment in the daily lives of formerly incarcerated individuals. My preliminary expectations are that the public will value relationship-building (a traditionally feminine ideal) more for formerly incarcerated women than for formerly incarcerated men. Additionally, I hypothesize that respondents will exhibit a greater willingness to interact with formerly incarcerated women as compared to their male counterparts, due to negative stereotypes about male aggression and criminality. The implications of this research extend to a broader understanding of the obstacles faced by individuals with criminal records in achieving successful rehabilitation. My analysis will help create more targeted and effective reintegration support policies by uncovering how public stigma impacts the reentry outcomes for women differently than for men. Addressing these dynamics is crucial for fostering inclusivity and dismantling barriers that impede the social and economic participation of formerly incarcerated individuals.

Air pollution is a key component to understanding the Public Health of populations globally, with Diesel Exhaust Particles (DEP) being a significant contributor to traffic-related air pollution. Exposure to DEPs varies across populations and is therefore crucial to understanding the continual impacts of traffic-related air pollution on the public. Prior research has indicated that the formation of Amyloid-𝛽 (A-𝛽) plaques and activation of the  nucleotide-binding domain, leucine-rich–containing family, pyrin domain–containing-3 (NLRP3) inflammasome is linked with the development of Alzheimer’s disease (AD) later in life. AD is a form of progressive disease that impairs memory and other cognitive functions and impacts the lives of tens of millions of people globally. This study aims to confirm the linkage between exposure to DEP and memory impairment through NLRP3 inflammasome activation, utilizing an animal model to investigate a potential increase in AD later in life. We exposed male and female low-density lipoprotein receptor knockout (LDLR KO) mice chronically to inhaled DEP or filtered air as a control for 18 weeks. We then utilized the Object Location Memory (OLM) and Object Recognition Memory (ORM) behavioral tests to investigate the immediate impact of multi-week DEP exposure on short-term memory, another indicator in AD progression. Afterward, we sacrificed the mice and harvested a variety of tissues, including the brain. I conducted Immunohistochemistry (IHC) on cryosections of the exposed and non-exposed brain to assess DEP-induced AD-like brain architectural changes and to quantify the impact of DEP exposure in activating the NLRP3 inflammasome, ultimately leading to neurotoxicity, and to the development and progression of AD. Confirming the association between diesel exhaust and the NLRP3 pathway provides a potential therapeutic target in populations at an elevated risk for AD.

Inhalation toxicology is a rising field of study as respirable toxicants become increasingly prevalent in our environment. Our research focuses on commonly inhaled toxicants: diesel exhaust (DE) and electronic cigarette aerosols (e-cig). Exposure to traffic-related air pollution and the use of e-cigs has rapidly increased, yet molecular pathways and health effects, and innate factors that impact health outcomes, remain largely unexplored. To assess cardiometabolic and neurodegenerative effects of DE, we exposed male and female mice (low-density lipoprotein receptor knockout, Ldlr KO) to filtered air or freshly generated DE for 18 weeks while fed a high-fat or Chow diet. We then conducted Object-Recognition and Object-Location Memory neurobehavioral tests to assess cognition, specifically hippocampus-independent recognition memory and hippocampus-dependent spatial memory and discrimination, respectively. We sacrificed mice and harvested brain, liver, and lung tissue for histopathological staining and biochemical measurements, including 3-nitrotyrosine, a biomarker of oxidative stress, via Western blot. To assess cardiopulmonary effects of e-cig aerosols, we exposed different mouse strains to acute (5 days) and chronic (3 months) e-cig aerosols with and without nicotine. We then harvested lung tissue and quantified glutathione (reduced and oxidized), an antioxidant and essential nucleophilic scavenger of electrophiles, via high-pressure liquid chromatography; and protein 3-nitrotyrosine. Statistical analyses of all the results obtained were carried out using R. Initial results revealed sex differences in biomarker levels between control and exposed mice. We plan to expand analyses by measuring an additional biomarker of oxidative stress, 8-oxo-dG. Additionally, we will quantify heavy metal accumulation in liver and brain in DE-exposed mice, along with metabolites of carcinogens such as acrolein in e-cig exposed mice. Forthcoming measurements will provide a more comprehensive understanding of biological responses to exposures and elucidate potential health implications. Our research in inhaled toxicants helps reveal critical insights for emerging public health challenges.