A crystal structure prediction enigma solved: the gallic acid monohydrate system – surprises at 10 K

Hoser, Anna A.; Şovago, Ioana; Lanza, Arianna; Madsen, Anders Ø.

doi:10.1039/c6cc06799a

Cited by 13 publications

(16 citation statements)

References 21 publications

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“…Organic molecules which crystallize with multiple molecules in the asymmetric unit, referred to as Z ′ > 1 or high- Z ′ structures, − continue to fascinate researchers, although several groups in the past have attempted to understand the Z ′ > 1 phenomenon. − The Cambridge Structural Database (CSD) reached a major milestone by depositing the millionth crystal structure in 2019 . The recent statistics of Z ′ > 1 in the CSD continue to be approximately 10–11% in organic structures and 8% in total CSD structures. − ,, A proper understanding of Z ′ and the expectation of a possible Z ′ > 1 crystal structure based on the molecular structure, functional groups, shape, and symmetry is regarded as an important strategy for an accurate crystal structure prediction (CSP) of drug molecules, − a structure determination by the powder X-ray diffraction (PXRD) method, − and the development of chiral materials. , The Z ′ > 1 structures are often termed as “frustrated” structures which are thought to arise from packing difficulties to crystallize as a single molecular entity . Steed wrote two detailed reviews on high- Z ′ structures, and the reasons for Z ′ > 1 occurrence are attributed to awkward molecular shape, the choice of slightly different molecular conformations, conflict from strong intermolecular interactions and crystal packing, pseudosymmetry, disorder, and temperature effects. , Experimental conditions under which the crystals are grown are shown to have a strong correlation with Z ′ > 1 behavior. , The connection between high- Z ′ structures and strong hydrogen bonds was noted by Gavezzotti, Nangia, Desiraju, Brock, , and others. …”

Section: Introductionmentioning

confidence: 99%

Conformational Polymorphism in Safinamide Acid Hydrochloride (Z′ = 3 and Z′ = 1) and Observation of a Temperature-Dependent Reversible Single-Crystal to Single-Crystal Phase Transformation of High-Z′ form (Z′ = 3 ↔ Z′ = 2 via an Intermediate Z′ = 4)

Nanubolu

2020

Crystal Growth & Design

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Two concomitant polymorphs of safinamide acid hydrochloride were obtained in an attempt to prepare the O-protonated amide salt of safinamide from ethanolic HCl solution. Polymorph I crystallized in the triclinic space group P1 with three molecules in the asymmetric unit (Z′ = 3) while polymorph II crystallized in the orthorhombic space group P2 1 2 1 2 1 with a single molecule in the asymmetric unit (Z′ = 1). Structural differences at the conformational level and their influence on intermolecular interactions in the crystals led to the occurrence of polymorphism in the title compound. Both Z′ = 1 and Z′ = 3 polymorphic forms of safinamide acid hydrochloride were sustained by similar strong O−H••• Cl − and N + −H•••Cl − hydrogen-bonded interactions but differed significantly in the molecular conformations and hence their molecular arrangements in the crystal lattice. The C−H•••O and C−H•••F hydrogen bonds along with the strong hydrogen bonds facilitated one-dimensional supramolecular aggregates and caused the occurrence of the Z′ > 1 situation. The high-Z′ polymorph showed an interesting phase transition behavior during variable-temperature single-crystal X-ray diffraction studies (VT-SCXRD). When the sample was rapidly cooled from 293 K (room temperature) to 100 K (low temperature), the Z′ = 3 polymorph was stable; however, when the same crystal was subjected to gradual cooling from room temperature to 100 K, the Z′ = 3 polymorph transformed to a novel Z′ = 2 structure (in the transition temperature range 260−265 K). When the sample was warmed from 100 K to RT, the phase transition was found to be reversible from Z′ = 2 to Z′ = 3 (in the transition temperature range 270−275 K). Differential scanning calorimetry studies were conducted to confirm the reversible phase transition nature (Z′ = 3 ↔ Z′ = 2). An intermediate short-lived crystal form with four molecules in the asymmetric unit (Z′ = 4) was captured at 272 K during the VT-SCXRD warming cycle, which facilitated a better understanding of the structural reorganization process during the phase transition. The Z′ = 4 structure can be referred as a "crystal on the way" in the Z′ = 2 to Z′ = 3 phase transition. The close structural similarities among Z′ = 3, 2, and 4 accounted for the phase transformation in a single-crystal to single-crystal manner.

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Section: Introductionmentioning

confidence: 99%

Conformational Polymorphism in Safinamide Acid Hydrochloride (Z′ = 3 and Z′ = 1) and Observation of a Temperature-Dependent Reversible Single-Crystal to Single-Crystal Phase Transformation of High-Z′ form (Z′ = 3 ↔ Z′ = 2 via an Intermediate Z′ = 4)

Nanubolu

2020

Crystal Growth & Design

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“…However, the three symmetry-independent SMZ molecules could not be clearly distinguished by the single crystal XRD data due to the higher level of molecular vibrations at temperatures above 100 K. Fortunately, the different local domains were captured by solid state NMR at room temperature due to the short time scale of NMR, on the order of milliseconds. 18,19 A very similar case, gallic acid monohydrate (GAM) form IV, was recently reported, where the accurate Z′ = 3 structure was solved at 10 K. 20 The motivation for investigating the crystal structure of GAM form IV at such a low temperature was its failure in the crystal structure prediction (CSP) blind tests. 21 A mechanistic understanding of these failure cases is essential for the further development of CSP methods.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Structural Features of Sulfamethizole and Its Cocrystals: Beauty Within

Yuan

Wang

et al. 2019

Crystal Growth & Design

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Sulfamethizole (SMZ) is an antibiotic drug with good solubility but short in vivo half-life. Thus, reducing the dissolution rate is expected to improve bioavailability and therapeutic activity through reducing the systemic elimination of SMZ. To this end, two novel pharmaceutical cocrystals, SMZ–sarcosine (SMZ–SAR) and SMZ–saccharin (SMZ–SAC), were designed and prepared according to the structural resemblance strategy. These cocrystals, along with a previously obtained SMZ–l-proline (SMZ–l-PRO) cocrystal, present an opportunity for detailed analysis of the crystal structure to identify key intermolecular interactions that guide their molecular assembly. 13C Solid state NMR data suggested more than one symmetry independent molecules in SMZ (Z′ > 1), which was confirmed by the SMZ crystal structure solved at 100 K (Z′ = 3). The amine–carboxylate synthon plays an important role in the intermolecular hydrogen bonding interactions of both SMZ–SAR and SMZ–l-PRO. In contrast, no strong intermolecular hydrogen bonding and π···π stacking interactions between SMZ and SAC were observed in SMZ–SAC, which features a shape-fit structure. Additionally, all cocrystals demonstrated lower equilibrium solubility and intrinsic dissolution rates compared to SMZ. Therefore, they are suitable crystal forms for the possible improvement in therapeutic performance of SMZ.

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“…The latter might indicate disorder over two sites of the polar phenol hydrogen atom as seen in related structures (e.g. phloroglucinol, 37,38 gallic acid 17,39 ). In case of form II, no isostructural packings were found in Fig.…”

mentioning

confidence: 95%

The trimorphism of 3-hydroxybenzoic acid: an experimental and computational study

Braun

2021

CrystEngComm

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A crystal structure prediction enigma solved: the gallic acid monohydrate system – surprises at 10 K

Cited by 13 publications

References 21 publications

Conformational Polymorphism in Safinamide Acid Hydrochloride (Z′ = 3 and Z′ = 1) and Observation of a Temperature-Dependent Reversible Single-Crystal to Single-Crystal Phase Transformation of High-Z′ form (Z′ = 3 ↔ Z′ = 2 via an Intermediate Z′ = 4)

Conformational Polymorphism in Safinamide Acid Hydrochloride (Z′ = 3 and Z′ = 1) and Observation of a Temperature-Dependent Reversible Single-Crystal to Single-Crystal Phase Transformation of High-Z′ form (Z′ = 3 ↔ Z′ = 2 via an Intermediate Z′ = 4)

Structural Features of Sulfamethizole and Its Cocrystals: Beauty Within

The trimorphism of 3-hydroxybenzoic acid: an experimental and computational study

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