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Molecular structures and dynamics in amorphous materials present unique experimental challenges compared with the characterization of crystalline solids. Liquids and glassy solids have many applications in industry such as ionic liquids for fuel cells or biomolecule stabilizing agents, enhancing pharmaceuticals

Molecular structures and dynamics in amorphous materials present unique experimental challenges compared with the characterization of crystalline solids. Liquids and glassy solids have many applications in industry such as ionic liquids for fuel cells or biomolecule stabilizing agents, enhancing pharmaceuticals dissolution rates, and modified high performance biopolymers like silk for textile, biomedical, drug delivery, among many others. Amorphous materials are metastable, with kinetic profiles of phase transitions depending on relaxation dynamics, thermal history, plus factors such as temperature, pressure, and humidity. Understanding molecular structure and phase transitions of amorphous states of small molecules and biopolymers is broadly important for realizing their applications. The structure of liquid and glassy states of the drugs carbamazepine (CBZ) and indomethacin (IMC) were studied with solid-state nuclear magnetic resonance (ssNMR) spectroscopy, high energy X-ray diffraction, Fourier Infrared Transform Spectroscopy (FTIR), differential scanning calorimetry (DSC), and Empirical Potential Structure Refinement (EPSR). Both drugs have multiple crystalline polymorphs with slow dissolution kinetics, necessitating stable glassy or polymer dispersed formulations. More hydrogen bonds per CBZ molecule and a larger distribution of oligomeric states in the glass versus the liquid than expected. The chlorobenzyl ring of crystalline and glassy IMC measured with ssNMR were surprisingly found to have similar mobility. Crucially, humidity strongly affects glass structure, highlighting the importance of combining modeling techniques like EPSR with careful sample preparation for proper interpretation. Highly basic protic ionic liquids with low ∆pKa were synthesized with metathesis rather than proton transfer and characterized using NMR and dielectric spectroscopy. Finally, the protein secondary structure of spider egg sac silk was studied using ssNMR, FTIR, and scanning electron microscopy. Tubuliform silk found in spider egg sacs has extensive β-sheet domains which form nanocrystallites within an amorphous matrix. Structural predictions and spectroscopic measurements of tubuliform silk solution are mostly α-helical, with the mechanism of structural rearrangement to the β-sheet rich fiber unknown. The movement of spiders during egg silk spinning make in situ experiments difficult practically. This work is the first observation that tubuliform silk of Argiope aurantia after liquid crystalline spinning exits the spinneret as a predominantly (~70%) β-sheet fiber.
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    Title
    • Molecular Structure in Amorphous Pharmaceuticals and Biopolymers
    Contributors
    Date Created
    2022
    Resource Type
  • Text
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    Note
    • Partial requirement for: Ph.D., Arizona State University, 2022
    • Field of study: Chemistry

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