Scholarship & Research
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Item Illuminating dynamic phenomena within organic microstructures with time resolved broadband microscopies(Montana State University - Bozeman, College of Letters & Science, 2024) Hollinbeck, Skyler Robert; Chairperson, Graduate Committee: Erik Grumstrup; This is a manuscript style paper that includes co-authored chapters.Materials derived from organic chromophore subunits are currently at the forefront of academic and industrial interest. This strong interest is driven in part by the tunability of their extant properties through engineering of both the intra-molecular and inter-molecular structure. The structure of organic materials affects optoelectronic properties because organic chromophores are sensitive to dipole-dipole and charge-transfer coupling interactions. This sensitivity presents both opportunities for tuning functional properties through designing specific packing geometries, and liabilities arising from the disruptive effects of structural disorder. Many organic materials are built from weak noncovalent interactions between chromophores, leading solid-state deposition, and crystallization to be susceptible to microscopic variations in environmental conditions. Structural heterogeneity is regularly intrinsic to organic materials, and even self-assembled systems of covalently linked chromophores exhibit defects. Ergo, in order to disentangle the effects of structural heterogeneity from the inherent properties of the material, the study of organic materials must be anchored with techniques that are capable of correlating optoelectronic properties and excited state evolution with microscale morphological characteristics. We have employed broadband pump-probe microscopies, in conjunction with steady-state and time resolved fluorescence techniques, to examine the effects of structure and coupling on excited state dynamics in solid-state organic microstructures. The study of perylene diimide (PDI) materials revealed that kinetically trapping PDI (KT-PDI) enhanced long-range ordering and led to distinct excited state evolution, delocalized charge-transfer states and long-lived charge separated species. In the MOF PCN-222, excitation energy dependent excited state behavior was observed. Pumping the first excited state (Q-band) led to immobile excited states that were relatively unaffected by local defect densities, whereas pumping the second excited state (Soret-band) led to mobile subdiffusive excited state species whose lifetimes are significantly impacted by morphologically correlated defect sites. Finally, we present progress made toward the construction and utilization of a frequency modulated-femtosecond stimulated Raman microscope, yielding spectra that resolve the location of photoinduced anion formation in KT-PDI. The work presented herein highlights broadband time-resolved microscopy as a potent tool for studying the structure-function relationship and photophysical behavior in molecular solids, deepening our understanding of how structural characteristics influence excited state evolution.Item The synthesis and characterization of fluorescently labeled, lactose-functionalized poly(amidoamine) (PAMAM) dendrimers(Montana State University - Bozeman, College of Letters & Science, 2024) Frometa, Magalee Rose; Chairperson, Graduate Committee: Mary J. CloningerCellular uptake of lactose-functionalized poly(amidoamine) dendrimers (PAMAM) has yet to be fully understood and deeply studied. Before sufficient cellular uptake studies can be made, optimization of the synthesis of the lactoside, and the coupling and purification of dye-tagged lactose-functionalized PAMAM had to be completed, as reported here. The synthesis of the requisite lactoside derivative for dendrimer functionalization was optimized. The coupling of the dye, Alexa Fluor 647, to the lactoside-functionalized PAMAM was performed in the presence of a sodium acetate buffer and utilized size separation methods to ensure purity. The structures of the lactoside derivatives and of lactose functionalized PAMAMs were confirmed via nuclear magnetic resonance (NMR) spectroscopy. The purity and degree of labeling (DOL) of the dye labeled, lactose-functionalized PAMAMs were determined with UV-vis. Results show high success of yield and purity resulting from the optimized procedure described in this study.Item Single cell encapsulation, detection, and sorting of Pseudomonas syringae using drop-based microfluidics(Montana State University - Bozeman, College of Engineering, 2023) Lindsay, Travis Carson; Chairperson, Graduate Committee: Abigail Richards; Connie Chang (co-chair)Bacteria can survive antibiotic or bactericidal treatment through genetic mutations. Even within bacterial populations that are fully susceptible to treatment, a small proportion of cells can have enhanced survival capacity in a phenomenon called persistence. Traditional microbiology methods can fail to identify or isolate these persister cells present within the population. A novel method for high-throughput single cell analyses of microbial populations is that of drop-based microfluidics, in which individual cells can be isolated within picoliter-sized drops. In this work, fluorescent detection and dielectrophoresis-based sorting of drops was developed for isolating Pseudomonas syringae persister cells following antimicrobial treatment. We demonstrate: (1) the dielectrophoresis-based sorting of dye-filled 25 micron drops based upon two colors, (2) differences between laser-induced fluorescent detection of dyes compared to single bacterial cells, (3) single-cell isolation of P. syringae into 25 micron droplets with ~10% of droplets containing singlecells, and (4) the treatment, staining, and fluorescent characterization of P. syringae at 0.5x, 5x, and 50x the minimum inhibitory concentration of carbonyl cyanide m-chlorophenyl hydrazone (CCCP), an antibiotic which resulted in 6.2%, 10.2%, and 88.6% cell death of the population, respectively. These results provide the groundwork for studying antibiotic-treated P. syringae and the isolation of surviving cells that will lend insight into the molecular basis of persistence for preventing recurrent infections and decreasing the likelihood of antibiotic resistance.Item Improving the two-photon absorption properties of fluorescent proteins for neuroscience(Montana State University - Bozeman, College of Letters & Science, 2020) Molina, Rosana Sophia; Chairperson, Graduate Committee: Thomas Hughes; Yong Qian, Jiahui Wu, Yi Shen, Robert E. Campbell, Mikhail Drobizhev and Thomas E. Hughes were co-authors of the article, 'Understanding the fluorescence change in red genetically encoded calcium ion indicators' in the journal 'Biophysical Journal' which is contained within this dissertation.; Tam M. Tran, Robert E. Campbell, Gerard G. Lambert, Anya Salih, Nathan C. Shaner, Thomas E. Hughes and Mikhail Drobizhev were co-authors of the article, 'Blue-shifted green fluorescent protein homologues are brighter than enhanced green fluorescent protein under two-photon excitation' in the journal 'The Journal of physical chemistry letters' which is contained within this dissertation.; Jonathan King, Jacob Franklin, Nathan Clack, Christopher McRaven, Vasily Goncharov, Daniel Flickinger, Karel Svoboda, Mikhail Drobizhev, Thomas E. Hughes were co-authors of the article, 'An instrument to optimize fluorescent proteins for two-photon excitation' which is contained within this dissertation.Untangling the intricacies of the brain requires innovative tools that power basic research. Fluorescent proteins, first discovered in jellyfish, provide a genetically encodable way to light up the brains of animal models such as mice and fruit flies. They have been made into biosensors that change fluorescence in response to markers of neural activity such as calcium ions (Ca 2+). To visualize them, neuroscientists take advantage of two-photon excitation microscopy, a specialized type of imaging that can reveal crisp fluorescence images deep in the brain. Fluorescent proteins behave differently under twophoton excitation compared to one-photon excitation. Their inherent two-photon properties, namely brightness and peak absorption wavelength, limit the scope of possible experiments to investigate the brain. This work aims to understand and improve these properties through three projects: characterizing a set of red fluorescent protein-based Ca 2+ indicators; finding two-photon brighter green fluorescent proteins; and developing an instrument to screen for improved fluorescent proteins for two-photon microscopy. Analyzing nine red Ca 2+ indicators shows that they can be separated into three classes based on how their properties change in a Ca 2+-dependent manner. In one of these classes, the relative changes in one-photon properties are different from the changes in two-photon properties. In addition to characterizing, identifying and directly improving fluorescent proteins for enhanced two-photon properties is important. Presented here is a physical model of the light-absorbing molecule within the green fluorescent protein (the chromophore). The model predicts that green fluorescent proteins absorbing at higher energy wavelengths will be brighter under two-photon excitation. This proves to be the case for 12 blueshifted green fluorescent proteins, which are up to 2.5 times brighter than the commonly used Enhanced Green Fluorescent Protein. A way to directly improve fluorescent proteins is through directed evolution, but screening under two-photon excitation is a challenge. An instrument, called the GIZMO, solves this challenge and can evolve fluorescent proteins expressed in E. coli colonies under two-photon excitation. These results pave the way for better two-photon fluorescent protein-based tools for neuroscience.