Browsing by Subject "crystallinity"

Solids most commonly come in two broad forms: crystalline or amorphous. Crystalline solids have a regular, organized long-range structure of atoms and crystals, and are characterized by having a distinct shape, specific volume, and melting point. They can also have multiple polymorphs. On the other hand, amorphous solids do not usually have a regular long-range atomic and crystal structure and their molecules are more easily separated, which makes them more soluble in their surroundings compared to crystalline solids. However, despite this, short-range order can also occur. To improve the solubility of crystalline solids, co-amorphous systems can be created by mixing together two or more chemically different compounds in a way that they don't form a regular crystalline structure, but rather an irregular, amorphous one. Co-amorphous systems can be analyzed qualitatively or quantitatively. Qualitative analysis is often the main focus when studying amorphous matter, as it can be difficult to accurately quantify these materials using techniques based on crystal structures. Additionally, many amorphous systems are made up of complex mixtures of polymers with different chemical and physical properties. This study aimed to determine the most effective method for obtaining quantitative information about the co-amorphization of indomethacin and tryptophan. Three analytical techniques were used for this purpose: differential scanning calorimetry (DSC), X-ray powder diffraction (XRPD), and Raman spectroscopy. The co-amorphous system was created by mixing together α-indomethacin and tryptophan, γ-indomethacin and tryptophan, and amorphous indomethacin and tryptophan. This study showed that DSC, XRPD, and Raman spectroscopy are effective in providing quantitative information about crystallinity and crystal size. These techniques were able to accurately detect and characterize discrete residual crystals, and were able to measure and quantify the amount of these substances. Even though these methods may not be able to detect nanoscale structures with precision, they still provided valuable information about the crystalline and amorphous nature of the samples studied. Additionally, the fact that similar quantitative results were obtained using different analysis methods further supports the reliability of these techniques. Of all the techniques discussed, Raman spectroscopy was able to identify even small residual crystals, resulting in the highest calculated crystallinity percentage.