This study was conducted to determine the difference in compressive strength between decayed and healthy teeth. The teeth were subjected to a compressive force to simulate the process of mastication. This was done to show that healthy teeth would be better at handling these compressive forces since they have more enamel. 26 teeth samples were collected (19 molars, 4 canines, and 3 premolars) evenly distributed between healthy and decayed. The samples were dimensionally analyzed using electronic calipers and then categorized as either decayed or healthy. The samples were then placed in a nut bolt with epoxy so that the samples could be compressed. Each sample was recorded on video while they were being exposed to the compressive force. This was done to observe how the samples were coming in contact with the Shimadzu compression machine. The amount of force that was required for the samples to exhibit the first point of breakage was recorded by the machine in pounds of force. Various analyses were conducted to determine relationships between several variables. The results showed that as the total and occlusal surface area increased, so did the amount of force the samples could absorb before breakage. As the machine came in contact with more cusps among the molar samples, those samples were able to absorb a larger compressive force. The average force that the decayed and healthy molar samples endured before breakage was roughly even, with the decayed samples average being slightly greater.
Stress is a necessary and functional part of human physiology. From responding to life-threatening situations to getting people out of bed in the morning, stress serves a major purpose in human survival. However, when consistent and high levels of stress are experienced, it can pose a threat to human health. One of the major mediators of physiological stress is a hormone called cortisol. Cortisol is a well-defined substance and its function in normal physiology is well understood. Scientific research indicates that consistent and high levels of this hormone may be an aid in cancer’s ability to evade the human immune response. Despite this, there is not much known about its relationship with cancer. I used immunofluorescence to determine cell-to-cell variability of vimentin expression and DNA content for cells that were exposed to cortisol at consistent and frequent doses overtime and those not exposed to cortisol to determine if cortisol altered the variability of vimentin expression and DNA content. I observed no change in the variability in vimentin expression across both cell conditions. I did observe variability in DNA content across both cell conditions, with more variability in the population affected by cortisol. These results suggest that there might be a relationship between the stress induced by cortisol, taking place at the genomic level but may have no impact on specific protein expression. Potential implications of the research conducted are looks to preventative medicine in the context of stress experienced by members of marginalized groups as a way of preventing cancer development.
To test this, Saccharomyces cerevisiae was utilized. This is a primary model used in most medicinal studies due to the resemblance to human cells. This study evaluates the effect of ferulic acid, concentrations on ultraviolet radiated Rad 1 (mutant) and HB0 (wild type) yeast cells. The yeast strains were grown in two different concentrations for ferulic acid and treated with long-wave UV light under 30 seconds, 45 seconds, and 60 seconds. It is observed that, Rad 1 had heavier growth in the presence of high concentration of ferulic acid after UV treatment than HB0. But, HB0 yeast had heavier growth in the presence of lower concentrations of ferulic acid after UV treatment. Ferulic acid concentrations of 1 mM can influence cell repair after UV application by mRNA expression during nucleotide excision repair and higher absorption of UV.