AI Article Synopsis
- Four novel cocrystals of xanthohumol (XN) were created with coformers—nicotinamide, glutarimide, acetamide, and caffeine—using a slow evaporation method.
- The crystal structures were analyzed through X-ray diffraction, revealing stable layered packing due to various hydrogen bonds and interactions among the molecules.
- Spectroscopy confirmed that the cocrystals were unique phases influenced by intermolecular interactions, and solubility studies showed a significant increase in solubility for XN-AC compared to pure XN.
Article Abstract
Four novel xanthohumol (XN) cocrystals with pharmaceutically acceptable coformers, such as nicotinamide (NIC), glutarimide (GA), acetamide (AC), and caffeine (CF) in the 1:1 stoichiometry were obtained by the slow evaporation solution growth technique. The structure of the cocrystals was determined by single crystal X-ray diffraction. The analysis of packing and interactions in the crystal lattice revealed that molecules in the target cocrystals were packed into almost flat layers, formed by the O-HO, O-HN, and N-HO-type contacts between the xanthohumol and coformer molecules. The results provided details about synthons responsible for crystal net stabilization and all hydrogen bonds observed in the crystal lattice. The main synthon was formed via the hydrogen bond between the hydroxyl group in the B ring of XN and coformers. The three-dimensional crystal lattice was stabilized by the hydrogen XN-XN interactions whereas the π-π stacking interactions played an additional role in layer binding, with the exception of low quality cocrystals formed with caffeine. Application of FTIR and Raman spectroscopy confirmed that the crystalline phase of obtained cocrystals was not a simple combination of individual components and completely different crystal phases resulted from the effect of intermolecular interactions. The multivariate analysis showed the changes in the spectra, and this technique can be applied in a combination with vibrational spectroscopy for fast screening of new crystal phases. Additionally, the solubility studies of pure XN and its cocrystals exhibited a 2.6-fold enhancement in XN solubility in aqueous solution for XN-AC and, to a lesser extent, for other cocrystals.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6930654 | PMC |
| http://dx.doi.org/10.3390/molecules24234245 | DOI Listing |
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