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Genetically Engineered Wound Dressing for Sensing and Treating Candida albicans Infections in Diabetic Foot UlcersKurowski, Anna Rose 12 June 2024 (has links)
Master of Science / A quarter of diabetics suffer from diabetic foot ulcers due to chronic nerve damage, a leading complication found in many patients. Symptoms cause changes in the skin's environment, leading to frequent cuts in the skin. This often results in recurrent foot ulcers that are at high risk of infections. Currently, typical treatments take the form of antibiotics, which can lead to serious fungal or yeast infections. Candida albicans is one of the leading non-bacterial pathogens causing infections in diabetic foot ulcers, and if left untreated, these infections can progress into candidiasis. Candidiasis causes inner tissue damage that often requires amputations or, in severe cases, enters the bloodstream, leading to death. Candida infections are typically treated with azoles like fluconazole. There is an unmet need to develop new strategies to detect and treat Candida infections. In this work, we developed hydrogel-based Engineered Living Materials (ELMs) as an antifungal wound dressing. Additionally, to increase the efficacy of engineered antifungal dressing, we develop a genetic drug releasing system in the presence of blue light. Thus, here we describe the fundamental work-frame for the development of smart wound dressing to treat various fungal and bacterial infections.
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Bacteria - Hydrogel Interactions: Mechanistic Insights via Microelastography and Deep LearningKarmarkar, Bhas Niteen 05 January 2024 (has links)
Bacteria-based cancer therapy (BBCT) holds immense promise in addressing the limitations in treatment of solid tumors. Bacterial strains used for BBCT are engineered to express therapeutics, facilitate precise navigation within the tumor microenvironment by enhancing bacteria's motility, chemotaxis (movement toward or away from specific chemicals), or other mechanisms that aid in reaching and infiltrating the tumor tissue effectively, and complementing traditional chemotherapy and immunotherapies while minimizing side effects. Bacterial motility not only influences the ability of bacteria to navigate within the tumor but also plays a pivotal role in optimizing drug delivery, treatment efficacy, and minimizing potential obstacles associated with the complex microenvironment of human tissues. However, the current understanding of bacterial motility remains limited. In this thesis, we use a reductionist approach and study bacteria motile behavior within human tissue phantoms (collagen and agar) and the bacteria-hydrogel interactions. Apart from motility, it is important to analyze the mechanical properties of the hydrogels the bacteria interact with as they play a vital role in overall behavior and physics of bacteria movement. To that extent, there exists a gap in our understanding of the viscoelastic properties of hydrogels. Lastly, systematic and comprehensive investigation of bacteria behavior in hydrogels requires tracking of thousands of individual cells. Thus, there is an unmet need to develop new automated techniques to reduce the labor-intensive manual tracking of bacteria in low-contrast hydrogel environments, with feature sizes comparable to that of bacteria. To address these gaps, this thesis proposes a trident approach towards mechanistic understanding of bacteria motility in time-invariant agar and temporally evolving collagen hydrogels to bridge critical gaps in understanding bacterial motile behavior in these media, non-destructive microelastography-based mechanical characterization of hydrogels with less than 4.7% error compared with rheology, and the development of deep learning-enabled automated bacteria tracking tools with 77% precision. / Master of Science / There exists a huge scope for improvement in cancer therapies. The gold standard chemotherapy and immunotherapies are responsible for a lot of side effects. Over a century ago, bacteria-based cancer therapy started to develop and over the period, it was discovered that they can be effective when used with traditional therapies improving precision and reducing side effects. The motility of bacteria is shown to improve bacterial distribution in solid tumors. However, the physical underpinnings of bacteria motility in the tumor environment remains understudied. This thesis proposes a trident approach, investigating bacteria motility in tissue-like environments (hydrogels), characterizing the mechanical properties of hydrogels using acoustic waves to capture bacteria-induced alterations, and developing deep-learning-enabled automated bacterial tracking approach for high throughput analysis of experimental data. We report bacteria behavior and motility patterns in hydrogels, the mechanics of these hydrogels with less than 4.7% error compared with standard characterization methods, and automated bacteria tracking with 77% precision to inform the development and advancement of bacteria-based drug delivery systems. In summary, these tools can help improve our understanding of bacteria-hydrogel interactions, allowing us to develop innovative bacteria-based cancer therapies in the long term.
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