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Development of an in vitro model to study the impact of substrate strain on uterine smooth muscle cell hypertrophyMarr, Elizabeth E. 31 May 2022 (has links)
In 2018, 1 in every 10 infants born in the United States was born preterm. The majority of neonatal deaths and nearly a third of infant deaths that occur are linked to preterm birth. Preterm birth is initiated when the quiescent state of the uterus ends prematurely, leading to contractions and parturition beginning as early as 32 weeks, though the origins are not well understood. Tocolytics are pharmaceuticals utilized to postpone preterm labor, but currently only manage to prolong pregnancy for up to 48 hours and have not proven effective in completely preventing preterm delivery. To enable research and discovery of therapeutics with potential to better address preterm birth, the capability to study isolated cell processes of pregnant uterine tissue in vitro is needed. Our development of an in vitro model of the myometrium utilizing uterine myocytes - uterine smooth muscle cells (uSMCs) responsible for contractions - provides a platform to examine the cellular mechanisms of late-stage pregnancy potentially involved in preterm birth. In this thesis, we discuss the optimized culture of uterine SMCs on a flexible polydimethylsiloxane (PDMS) substrate functionalized using a cationic solution, Poly-L-lysine (PLL), followed by extracellular matrix (ECM) protein coating. Using the model we developed, we then exposed this elastic substrate with uterine SMCs to different strain rates in order to investigate the impact of mechanical strain parameters on uterine SMC hypertrophy in the uterus during late-stage pregnancy. It was found that PLL and ECM protein coatings significantly impact cell morphology and density in unstrained substrates. It was also observed that when exposed to strain conditions, strain significantly increased hypertrophic morphological traits in select conditions. These results indicate that both surface and mechanical properties of in vitro systems impact uterine SMC phenotype, offering further understanding of cellular pathways involved in the uterus under mechanical load. / 2024-05-31T00:00:00Z
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