Lian et al., 2013 - Google Patents
Crystal engineering approach to produce complex of azelnidipine with maleic acidLian et al., 2013
- Document ID
- 10256997028535530323
- Author
- Lian W
- Lin Y
- Wang M
- Yang C
- Wang J
- Publication year
- Publication venue
- CrystEngComm
External Links
Snippet
A novel azelnidipine–maleic acid complex was prepared by the solvent-assisted co-grinding method. The obtained complex was characterized by powder X-ray diffraction (PXRD), differential scanning calorimetry (DSC), infrared (IR), Raman, solid-state nuclear magnetic …
- 239000011976 maleic acid 0 title abstract description 93
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Lin et al. | Preparation, characterization, and evaluation of dipfluzine–benzoic acid co-crystals with improved physicochemical properties | |
| Basavoju et al. | Indomethacin–saccharin cocrystal: design, synthesis and preliminary pharmaceutical characterization | |
| Vioglio et al. | Pharmaceutical aspects of salt and cocrystal forms of APIs and characterization challenges | |
| Liu et al. | Supramolecular assembly of perylene bisimide with β‐cyclodextrin grafts as a solid‐state fluorescence sensor for vapor detection | |
| Song et al. | Investigation from chemical structure to photoluminescent mechanism: a type of carbon dots from the pyrolysis of citric acid and an amine | |
| Paudel et al. | Structural and dynamic properties of amorphous solid dispersions: the role of solid-state nuclear magnetic resonance spectroscopy and relaxometry | |
| Deng et al. | Dapagliflozin-citric acid cocrystal showing better solid state properties than dapagliflozin | |
| Hong et al. | A novel strategy for pharmaceutical cocrystal generation without knowledge of stoichiometric ratio: myricetin cocrystals and a ternary phase diagram | |
| Lian et al. | Crystal engineering approach to produce complex of azelnidipine with maleic acid | |
| Chen et al. | Moisture-induced amorphous phase separation of amorphous solid dispersions: molecular mechanism, microstructure, and its impact on dissolution performance | |
| CN111638234B (en) | Method for detecting medicine with dicycloplatin as active ingredient | |
| Limwikrant et al. | Formation mechanism of a new carbamazepine/malonic acid cocrystal polymorph | |
| Kakran et al. | Dissolution enhancement of artemisinin with β-cyclodextrin | |
| Yamamoto et al. | Physicochemical evaluation and developability assessment of co-amorphouses of low soluble drugs and comparison to the co-crystals | |
| Aso et al. | Miscibility of nifedipine and hydrophilic polymers as measured by 1H-NMR spin–lattice relaxation | |
| Pan et al. | Solid state characterization of azelnidipine–oxalic acid co-crystal and co-amorphous complexes: The effect of different azelnidipine polymorphs | |
| Asbahr et al. | Binary and ternary inclusion complexes of finasteride in HPβCD and polymers: Preparation and characterization | |
| Ramu et al. | Lamotrigine novel cocrystals: An attempt to enhance physicochemical parameters | |
| Bejaoui et al. | Formation of water soluble and stable amorphous ternary system: ibuprofen/β-cyclodextrin/PVP | |
| Wang et al. | Solid-state characterization of 17β-estradiol co-crystals presenting improved dissolution and bioavailability | |
| Lugger et al. | Easily Accessible Thermotropic Hydrogen‐Bonded Columnar Discotic Liquid Crystals from Fatty Acid–Tris‐Benzoimidazolyl Benzene Complexes | |
| Gaglioti et al. | Improvement of the water solubility of tolfenamic acid by new multiple-component crystals produced by mechanochemical methods | |
| Li et al. | Solid state characterizations and analysis of stability in azelnidipine polymorphs | |
| Schmidt | The role of molecular structure in the crystal polymorphism of local anesthetic drugs: crystal polymorphism of local anesthetic drugs, part X | |
| Havelková et al. | Functionalized hyper-cross-linked porous homopolymers of ring-substituted 1, 3-diethynylbenzenes and their physisorption activity |