PURPOSE: To investigate the effect of temperature on hydrogen bonding in a series of structurally related amorphous and crystalline compounds to gain a better molecular-level understanding of structural differences in the various phases. METHODS: FT-infrared spectra of seven 1,4-dihydropyridine calcium channel blockers were obtained at temperatures between 0 and 200 degrees C using a temperature-controlled attenuated total reflection accessory. Thermal behavior was characterized using differential scanning calorimetry. RESULTS: Hydrogen bonding was investigated by monitoring the position of the NH stretching vibration, where an increase in peak wavenumber was taken to indicate a weakening of hydrogen bonding. Heating resulted in a reduction in hydrogen bonding strength, which was greatest for liquids and less for glassy and crystalline phases. For the amorphous samples, a plot of NH peak position vs. temperature displayed a discontinuity in the region of the glass transition (determined using differential scanning calorimetry) indicating that hydrogen bonding weakened abruptly as the material passed through the glass transition. This effect was more pronounced for some samples than for others. CONCLUSIONS: The variation in the decrease in hydrogen-bonding interactions with increasing temperature for the different phases is consistent with greater configurational freedom as one moves from crystal to glass to liquid.
PURPOSE: To investigate the effect of temperature on hydrogen bonding in a series of structurally related amorphous and crystalline compounds to gain a better molecular-level understanding of structural differences in the various phases. METHODS: FT-infrared spectra of seven 1,4-dihydropyridine calcium channel blockers were obtained at temperatures between 0 and 200 degrees C using a temperature-controlled attenuated total reflection accessory. Thermal behavior was characterized using differential scanning calorimetry. RESULTS:Hydrogen bonding was investigated by monitoring the position of the NH stretching vibration, where an increase in peak wavenumber was taken to indicate a weakening of hydrogen bonding. Heating resulted in a reduction in hydrogen bonding strength, which was greatest for liquids and less for glassy and crystalline phases. For the amorphous samples, a plot of NH peak position vs. temperature displayed a discontinuity in the region of the glass transition (determined using differential scanning calorimetry) indicating that hydrogen bonding weakened abruptly as the material passed through the glass transition. This effect was more pronounced for some samples than for others. CONCLUSIONS: The variation in the decrease in hydrogen-bonding interactions with increasing temperature for the different phases is consistent with greater configurational freedom as one moves from crystal to glass to liquid.
Authors: Claudia B Packhaeuser; Kerstin Lahnstein; Johannes Sitterberg; Thomas Schmehl; Tobias Gessler; Udo Bakowsky; Werner Seeger; Thomas Kissel Journal: Pharm Res Date: 2008-10-08 Impact factor: 4.200