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The severe resistance of bacteria and fungi towards common antibiotic drugs has led to the increasing prevalence of infections due to multi-drug resistant microbes, which is one of the most serious issue faced by the healthcare system worldwide. These drug-resistant

The severe resistance of bacteria and fungi towards common antibiotic drugs has led to the increasing prevalence of infections due to multi-drug resistant microbes, which is one of the most serious issue faced by the healthcare system worldwide. These drug-resistant bacteria have led to significant health problems and fatalities whereas drug-resistance fungi possess significant threat to humans, livestock, and crops globally. Furthermore, this drug resistance leads to the formation of biofilms, which are thick layers of microbes embedded in extracellular polymeric matrix. They adhere to both living and nonliving surfaces, making it harder to contain or eradicate these pathogens. The conventional strategy for combating these pathogenic bacteria and fungi has its limitations and new antimicrobials are constantly required to fight the growing resistant mechanisms. Hence, there is an immediate need for an alternative strategy to combat these drug-resistant isolates. Herein, this dissertation reports the development of novel potent antimicrobial agent based on tow-dimensional layered nanomaterials dispersed in biocompatible oligonucleotide, biomolecules, polymers, and surfactant. These synthesized novel nanomaterials successfully eliminated multidrug-resistant microbes with synergistic efforts of physical interaction, membrane disintegration, depolarization and intrinsic antimicrobial properties leading to cell death. These systems were highly effective against a broad spectrum of microbes including drug-resistant gram-positive, gram-negative bacteria and fungal isolates. Furthermore, they were successful in eradication of mature biofilm as well as inhibition of biofilms on several medically relevant surfaces. Overall, these novel systems have exceptional potential as a promising alternative solution in solving current problems faced by the healthcare system sue to these pathogenic microbes. For the next direction, a different avenue was explored where a novel system based on two-dimensional layered material with antibacterial properties was analyzed for enzyme-like activity. These nanomaterials with intrinsic enzyme-like properties are commonly known as nanozymes have many advantages over natural enzymes such as low cost, scalability and high stability. A class of ultra-high temperature ceramics known as metal diborides were synthesized in biocompatible surfactant followed by analysis of their enzymatic activity and antibacterial activity. Results demonstrate this novel system possesses a unique combination of exceptionally high affinity towards hydrogen peroxide and high activity per cost. Furthermore, it is extremely potent against pathogenic bacteria and has a high degree of biocompatibility. Hence, this new system opens the door for future possible applications in biomedicine with further research.
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    Title
    • Applications Of Two-Dimensional Layered Materials in Eradication of Multi-Drug Resistant Organisms and Natural Enzyme Mimicking Catalysis
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    Date Created
    2021
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    • Partial requirement for: Ph.D., Arizona State University, 2021
    • Field of study: Biochemistry

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