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Synthesis, powder diffraction pattern, crystal structure determination of the pharmaceutical co-crystal of levetiracetam and 3,5-dinitrosalicylic acid

Published online by Cambridge University Press:  16 October 2023

Lingling Shi
Affiliation:
School of Materials Science and Engineering, Zhejiang Sci-Tech University, Hangzhou 310018, People's Republic of China
Zhengguo Chen
Affiliation:
School of Materials Science and Engineering, Zhejiang Sci-Tech University, Hangzhou 310018, People's Republic of China
Hany Kafafy
Affiliation:
Dyeing, Printing and Auxiliaries Department, Textile Research Division, National Research Center, 33 El-Buhoth St, Dokki, Cairo 12311, Egypt
Zhaoxia Zhang
Affiliation:
School of Materials Science and Engineering, Zhejiang Sci-Tech University, Hangzhou 310018, People's Republic of China
Guocheng Zhu
Affiliation:
School of Materials Science and Engineering, Zhejiang Sci-Tech University, Hangzhou 310018, People's Republic of China
Juming Yao
Affiliation:
School of Materials Science and Engineering, Zhejiang Sci-Tech University, Hangzhou 310018, People's Republic of China
Guoqing Zhang*
Affiliation:
School of Materials Science and Engineering, Zhejiang Sci-Tech University, Hangzhou 310018, People's Republic of China
*
a)Author to whom correspondence should be addressed. Electronic mail: [email protected]
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Abstract

(S)-α-Ethyl-2-oxo-1-pyrrolidineacetamide (trade name levetiracetam), a derivative of piracetam, is used clinically as an add-on treatment for partial-onset seizures. In this study, we report the solid-state structure of a new drug co-crystal produced from levetiracetam and 3,5-dinitrosalicylic acid through cooling crystallization. This compound was further characterized by infrared spectroscopy, powder X-ray diffraction, and single-crystal X-ray diffraction. The new co-crystals show a 1:1 stoichiometry and crystallize in the monoclinic system, space group P21, with cell parameters: a = 9.7709(3) Å, b = 6.2202(2) Å, c = 14.7280(4) Å, α = 90°, β = 96.0340(10)°, γ = 90°, V = 890.16(5) Å3, and Z = 2. It is identified that hydrogen bonds are the main interactions between levetiracetam and 3,5-dinitrosalicylic acid, and the contribution of each hydrogen bond in maintaining the stability of the crystal structure was also quantified using Hirshfeld surface analysis.

Type
New Diffraction Data
Copyright
Copyright © The Author(s), 2023. Published by Cambridge University Press on behalf of International Centre for Diffraction Data

I. INTRODUCTION

Pharmaceutical co-crystal (El-Gizawy et al., Reference El-Gizawy, Osman, Arafa and El Maghraby2015; Ervasti et al., Reference Ervasti, Aaltonen and Ketolainen2015) is an application of the concept of supramolecular chemistry in the pharmaceutical industry (Bolla and Nangia, Reference Bolla and Nangia2016), which consists of active pharmaceutical ingredient (API) and co-crystal formers (CCF) bonded by non-covalent bonds (including hydrogen bonding, van der Waals forces, π-π stacking effects, etc.). Due to their unique physicochemical properties, co-crystals are often used as a new solid form to improve the physicochemical properties of drugs, such as solubility (Ranjan et al., Reference Ranjan, Devarapalli, Kundu, Vangala, Ghosh and Reddy2017), dissolution rate (Yamashita and Sun, Reference Yamashita and Sun2018), bioavailability (Yoshimura et al., Reference Yoshimura, Miyake, Kawato, Bando, Toda, Kato, Fukami and Ozeki2017; Emami et al., Reference Emami, Siahi-Shadbad, Adibkia and Barzegar-Jalali2018), hygroscopicity (Sopyan et al., Reference Sopyan, Fudholi, Muchtaridi and Sari2017), and chemical stability (Duggirala et al., Reference Duggirala, Frericks Schmidt, Lei, Zaworotko, Krzyzaniak and Arora2018). Thus, co-crystals are of extraordinary value for research in the direction of drugs. In fact, co-crystal drugs do not need to go through phase II approval in the clinic research because they are not considered as a new molecular entity, which will save a lot in terms of development costs.

Levetiracetam (LEV) is a pyrrolidone compound, chemically named (S)-α-ethyl-2-oxo-1-pyrrolidineacetamide as a new antiepileptic drug (Zhang et al., Reference Zhang, Li, Hu, Tian and Gao2010; Weijenberg et al., Reference Weijenberg, Brouwer and Callenbach2015). After extensive research, it was approved by the U.S. FDA in 1999 for the treatment of seizures and finally marketed as a second-generation antiepileptic drug. Levetiracetam is a safer drug for clinical use due to its high bioavailability, linear pharmacokinetics, low protein binding rate, minimal hepatic metabolism, rapid acquisition of stable blood concentrations, and minimal drug interactions.

Levetiracetam molecule contains amine and carbonyl groups (Figure 1(a)), which can act as donors or acceptors of hydrogen bonds, forming coordination compounds with some inorganic salts or organic acids. As a result, co-crystals can form easily through these interactions, further improving the physicochemical properties of levetiracetam. For example, Song et al. (Reference Song, Shemchuk, Robeyns, Braga, Grepioni and Leyssens2019) prepared ionic co-crystals of levetiracetam with CaCl2 and MgCl2, successfully improving the thermal stability of levetiracetam (Song et al., Reference Song, Shemchuk, Robeyns, Braga, Grepioni and Leyssens2019).

Figure 1. (a) Levetiracetam molecule containing amine and carbonyl groups; (b) 3,5-dinitrosalicylic acid (abbreviated DNS or DNSA, IUPAC name 2-hydroxy-3,5-dinitrobenzoic acid), an aromatic acid combined with compounds of various structures to form co-crystals; and (c) the LEV-DNS co-crystal prepared by the cooling crystallization method.

Organic acids are commonly used as co-crystal formers in drug research and development. Among them, 3,5-dinitrosalicylic acid (abbreviated DNS or DNSA, IUPAC name 2-hydroxy-3,5-dinitrobenzoic acid) as an aromatic acid can easily combine with compounds of various structures to form co-crystals (Figure 1(b)). Its carboxyl group can participate in various O–H⋯X hydrogen bonds for the formation of monoanionic dimer/trimer of 3,5-dinitrosalicylic acid (D'Ascenzo and Auffinger, Reference D'Ascenzo and Auffinger2015).

In this paper, 3,5-dinitrosalicylic acid as a co-crystal former is selected to combine with levetiracetam by non-covalent hydrogen bonds. The co-crystal was first prepared by the cooling crystallization method (Friscic and Jones, Reference Friscic and Jones2009) as shown in Scheme 3 of Figure 1(c). To further understand the conformation of the co-crystal of levetiracetam and 3,5-dinitrosalicylic acid, the crystal products were characterized by FTIR spectroscopy, powder X-ray diffraction, and X-ray single-crystal diffraction. In addition, the role of hydrogen bond was also quantified by Hirshfeld surface analysis (Spackman and Mckinnon, Reference Spackman and McKinnon2002; Clausen et al., Reference Clausen, Chevallier, Spackman and Iversen2010; Seth et al., Reference Seth, Saha, Ghosh and Kar2011a).

II. EXPERIMENTAL AND REFINEMENT

A. Sample preparations

The drug co-crystals were prepared by mixing levetiracetam and 3,5-dinitrosalicylic acid in a 1:1 molar ratio in pure water. The mixture was heated between 60 and 70 °C under stirring until completely dissolved. After 1 h, the solution was allowed to cool down slowly to room temperature until a large number of bright yellow precipitates formed. The precipitate was filtered and dried to obtain bright yellow co-crystal powder.

To obtain single crystals, 10 mg of the powder was put into a sample bottle containing 30 ml of methyl tert-butyl ether solvent. The mixture solution was shaken until completely dissolved and clear, and then placed in a dry and ventilated place for about a week. One can see that some yellowish crystals will gradually grow up with evaporation of methyl tert-butyl ether, subsequently a small amount of n-heptane as antisolvent was added into the bottle for storage of the crystals.

B. FTIR spectroscopy

The molecular structures of levetiracetam, 3,5-dinitrosalicylic acid, and the synthesized co-crystalline powder were determined by FTIR spectroscopy. All the powder samples were mixed and ground with KBr in a volume ratio of 1:100, respectively, then tested in a wave number range of 500 to 4000 cm−1 with a resolution of 4 cm−1 and a scan number of 32.

C. Powder X-ray diffraction (PXRD)

X-ray powder diffraction patterns were collected on a D8 Advance diffractometer (Bruker, Germany) under the condition of Cu 1 radiation (λ = 1.5406 Å). The tube voltage and current were set at 40 kV and 40 mA, respectively. The 1D detector was employed to collect XRD data over the 2θ range from 5° to 50° with a step size of 0.02° and a counting time of 0.2 s per step. By comparing the powder diffractograms of the API, co-former and co-crystal, it can be determined whether a new crystalline phase has formed.

D. Single-crystal X-ray diffraction and refinement

The block-shaped single crystals of LEV-DNS co-crystal were first obtained by recrystallization from methyl tert-butyl ether solution. A suitable crystal (0.49 × 0.23 × 0.15 mm3) was selected and mounted on a glass fiber support on a Bruker APEX-II CCD diffractometer. The crystal was kept at a steady T = 170 K during data collection.

The crystal data and structure refinement details are summarized in Table II. All non-hydrogen atoms were refined with anisotropic displacement parameters. All hydrogen atoms bound to carbon atoms are geometrically placed and refined, and their isotropic displacement parameters are derived from the C atoms to which they are attached. The U iso(H) values of all CH2 and CH3 groups were fixed to 1.2 and 1.5 times the U eq values of the attached C atoms, respectively. Similarly, the hydrogen atoms on the amino and hydroxyl groups were refined and optimized with isotropic displacement parameters based on U iso(H) = 1.2 U eq(N) and U iso(H) = 1.5 U eq(O). The O5–H5A distance of the carboxyl was restrained to 0.84 Å. Other H atoms were generated geometrically and refined using a riding model with hypomethyl C–H = 1.00 Å, U iso(H) = 1.2 U eq(C), methylene C–H = 0.99 Å, aromatic C–H = 0.95 Å, and U iso(H) = 1.2 U eq(C).

III. RESULTS AND DISCUSSION

A. FTIR spectroscopy

FTIR spectroscopy has long been associated with the study of molecular vibrational properties, particularly in relation to the different functional groups present in drugs. The hydrogen bond caused by phase change is directly related to the transformation of the vibration frequency of functional groups. That is the fundamental reason why FTIR can be employed to characterize the co-crystal (Kang et al., Reference Kang, Gu and Hu2017; Lin, Reference Lin2017). In this study, from the FTIR spectra of the two raw materials and the co-crystal (Figure 2), one can see that pure LEV shows two characteristic bands at 3360 and 3192 cm−1 corresponding to the symmetric and asymmetric stretching vibrations of N–H in the amide group, respectively. Unlike LEV, DNS shows a wide band between 3640 and 3200 cm−1, which is the result of tensile vibrations of O–H on its phenol and carboxyl groups under the influence of hydrogen bonds. In the FTIR spectrum of the LEV-DNS co-crystal, the N–H stretching vibration peak keeps essentially the same but the O–H stretching vibration peak almost disappears because of the formation of O–H⋯O hydrogen bonds. On the other hand, the absorption peak of the C=O group is red-shifted from 1680 cm−1 in LEV and 1700 cm−1 in DNS to 1670 cm−1, which is also due to the O–H⋯O hydrogen bonds between the C=O group and the ligand molecule, resulting in a decrease in the vibrational frequency of the carbonyl group and hence a blue-shift of the characteristic peak. This also shows that the carboxylic acid group remains neutral in the product of the reaction of LEV with DNS (Xu et al., Reference Xu, Jiang and Mei2014). Similarly, both DNS and LEV-DNS co-crystals show a characteristic peak belonging to nitro (–NO2) at 1337 cm−1, indicating that nitro is not involved in the reaction. Therefore, the FTIR data confirm that the co-crystals are indeed formed as suggested in Figure 2.

Figure 2. FTIR spectra of the levetiracetam (LEV), the 3,5-dinitrosalicylic acid (DNS) and the LEV-DNS co-crystal.

B. Powder X-ray diffraction (PXRD)

The PXRD pattern of a crystalline sample is considered as the fingerprint of its crystal structure. Every crystalline material will exhibit unique peaks indicative of diffraction from specific atomic planes (Newman and Byrn, Reference Newman and Byrn2003). The XRD patterns of levetiracetam (LEV), 3,5-dinitrosalicylic acid (DNS), and their co-crystal products (LEV-DNS) are shown in Figure 3(a).

Figure 3. (a) The PXRD patterns of LEV, DNS, and LEV-DNS co-crystal, (b) experimental and simulated XRD patterns of LEV-DNS co-crystal, and (c) Pawley refinement results.

As can be seen from the figure, the strong characteristic peaks are observed at 2θ 14.970°, 20.576°, and 30.102° for the LEV, while the peaks for DNS appear at 2θ 10.871°, 14.684°, and 21.679°. On the other hand, the strong characteristic peaks for the LEV-DNS co-crystal appear at 2θ 6.020°, 11.954°, and 17.989° which is completely different from the precursors. It is thus clear that the co-crystal product is not a simple physical mixing of the two raw materials, but indeed a new crystalline phase. Furthermore, from Figure 3(b), the experimental PXRD patterns from the grinding are in general agreement with the simulated patterns calculated from the structural parameters of the present LEV-DNS single crystals. The only difference in the relative intensities of some diffraction peaks can be attributed to changes in crystal habit or crystal size (Pandey et al., Reference Pandey, Sehal, Garg, Gaur, Kumar, Singh, Gulati, Gowthamarajan, Bawa, Rajesh, Sharma and Narang2017), further confirming the crystalline phase purity of the co-crystals (Figure 3(b)).

In order to obtain more accurate results, this paper uses the Reflex module in the Material Studio (Dassault Systèmes, 2021) software to perform Pawley refinement of the powder XRD pattern and then compares it with the simulated XRD data from the single crystals. As shown in Figure 3(c), the Pawley refinement, including the background, zero error, cell parameters, peak width, and peak symmetry parameters, was carried out successfully. The residuals of the final fit, R wp = 14.59% and R p = 10.13%, are less than 15%, which is an acceptable error range. The values of 2θ obs, d obs, I obs, h, k, l, 2θ cal, d cal, I cal, and Δ2θ are listed in Table I.

TABLE I. X-ray powder diffraction data of LEV-DNS co-crystal before and after Pawley refinement.

C. Single-crystal structure

From the single-crystal structure data listed in Table II, it can be seen that the space group of the obtained co-crystal is P21, belonging to the monoclinic system with cell parameters of a = 9.7709(3) Å, b = 6.2202(2) Å, c = 14.7280(4) Å, α = γ = 90°, and β = 96.0340(10)°. As a solvent-free compound, each asymmetric unit consists of two molecules of levetiracetam (LEV) and two molecules of 3,5-dinitrosalicylic acid (DNS) in a 1:1 ratio. There is no proton transfer between the LEV and DNS molecules, but linked together by hydrogen bonds to form a heterodimeric structure (Figure 4). In this dimer, the two DNS molecules are connected by a hydrogen bond N2–H2b⋯O1. DNS is linked to the LEV molecule through two hydrogen bonds, O5–H5A⋯O2 and O3–H3⋯O4, being represented by the graph set symbol as $R_2^2$(8) (Figure 5). The hydrogen bonding details and symmetry codes of the LEV-DNS co-crystal are given in Table III.

Figure 4. The molecular structures of LEV-DNS co-crystal show the atom-numbering schemes. Displacement ellipsoids are drawn at the 50% probability level. Dashed lines indicate hydrogen bonds.

Figure 5. Interactions occurring in the LEV-DNS co-crystal, the dashed lines represent hydrogen bonds.

TABLE II. Experimental details.

For the single-crystal structure: monoclinic, P21, Z = 2. Experiments were carried out at 170 K with Cu Kα radiation using a Bruker APEX-II CCD diffractometer. Absorption was corrected for by multi-scan methods.

TABLE III. Hydrogen-bond geometry (Å, °) for LEV-DNS co-crystal.

Symmetry codes: (i) 1−x, −1/+ y, 1−z.

In fact, the co-crystals formed by levetiracetam and 3,5-dinitrosalicylic acid are not coplanar, and the angle between the two planes formed by the connection of the two molecules is 35.59° (Figure 6(a)). The co-crystal's molecular arrangement, driven by hydrogen bonding, becomes apparent along the b-axis, resulting in the creation of a double-layered, one-dimensional chain reminiscent of the mathematical concept of an open root “$\sqrt {}$” (Figure 6(b)), with a distance of 6.607 Å between the two co-crystal molecules in the one-dimensional chain.

Figure 6. (a) Dihedral angle between LEV molecules and DNS molecules in an asymmetric structural unit and (b) intermolecular interaction diagram of LEV-DNS (along the b-axis).

D. Hirshfeld surface analysis

The intermolecular interactions of the LEV-DNS co-crystal were also studied in a targeted and visualized manner by CrystalExplorer software (Spackman et al., Reference Spackman, Turner, McKinnon, Wolff, Grimwood, Jayatilaka and Spackman2021). Figure 7(a) shows the Hirshfeld surfaces of the LEV-DNS co-crystal, where di is the shortest distance from the Hirshfeld surface to the inner atom and de is the shortest distance from the Hirshfeld surface to the outer atom (Spackman and Jayatilaka, Reference Spackman and Jayatilaka2009), and d norm is the surface map which depicts the individual hydrogen bonding interactions on the d norm surface. The 3D d norm surface is usually used to identify closer intermolecular interactions by taking into account the relative size of the atoms. In general, these are shown as red areas (relatively strong forces appearing as bright red or light red round spots) on the Hirshfeld surface when the length of the intermolecular interaction is shorter than r vdw (van der Waals (vdw) radius), conversely in white or blue when equal to or greater than r vdw.

Figure 7. (a) Hirshfeld surface generated over d norm, di and de for LEV-DNS co-crystal; (b) shape index; and (c) curvedness mapped over the Hirshfeld analysis.

The shape index represents the bumps (blue) and hollows (red) presented in the system (Figure 7(b)). It is clear that the crystal structure of the LEV-DNS does not exhibit any π…π stacking interaction since there is no evidence of the adjacent red and blue triangles on the shape index surface (Seth et al., Reference Seth, Maity and Kar2011b). In addition, the curvedness in the crystal structure shows the stacking of molecules in 3D space based on the presence of a flat green region (Figure 7(c); Soman et al., Reference Soman, Sujatha and Arunkumar2014).

The 2D fingerprint plots of intermolecular interactions reflect the way in which molecules interact within a structure and the extent to which each type of interaction contributes to the overall effect (Nikpour et al., Reference Nikpour, Mirzaei, Chen, Kaju and Bakavoli2009). As shown in Figure 8(a), the O⋯H/O⋯H intermolecular interactions exhibit a pair of symmetrical large spikes, characteristic of strong hydrogen bonding, and these interactions account for 41.5% of the total Hirshfeld surface area. H⋯H interactions also characterize a significant contribution to the Hirshfeld surface, accounting for 31.2% of the total surface area. Interactions between LEV-DNS co-crystals also include C⋯O/O⋯C interactions, but they do not dominate the crystal structure, accounting for only 13.7% of the total surface area. In addition, C⋯H/H⋯C and N⋯H/H⋯N interactions were present on only 3.8 and 2.5% of the total surface area, respectively (Figure 8(b)). It is clear that O–H⋯O hydrogen bonding is the major contributor to the interactions in this structure.

Figure 8. (a) The 2D fingerprint plot of various intermolecular interaction forces and (b) Pie chart of the relative contribution of various intermolecular interactions on the Hirshfeld surface.

IV. CONCLUSION

Although the antiepileptic drug levetiracetam has been available for many years, there is still relatively little information on its crystallographic aspects. In this paper, co-crystals of 3,5-dinitrosalicylic acid and levetiracetam were obtained by cooling (powder crystals) and solvent evaporation (single crystals) crystallization, subsequently a series of structural characterizations were carried out and analyzed.

The powder product formed after cooling crystallization can be identified by FTIR spectroscopy and X-ray diffraction, indicating the formation of the co-crystals. The single-crystal structure analysis reveals that the co-crystals of levetiracetam and 3,5-dinitrosalicylic acid are classified within the monoclinic crystal system, characterized by the P21 space group. These co-crystals are intricately connected through intermolecular hydrogen bonding forces, resulting in the formation of a distinctive structural motif. Specifically, these hydrogen bonding interactions give rise to a double layer of one-dimensional chains, adopting a unique shape resembling “$\sqrt {}$”. In addition, the Hirshfeld surface analysis and 2D fingerprints about LEV-DNS co-crystal reveal the degree of contribution of various intermolecular interaction forces. It is clear that the intermolecular hydrogen bonding forces are the main contributor to the overall interaction forces.

V. DEPOSITED DATA

The Crystallographic Information System file C8H14N2O⋅C7H4N2O7 co-crystal cif (for the single-crystal data) were deposited with the ICDD. The data files can be requested at [email protected].

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0885715623000374.

Funding statement

Funding for this research was provided by the National Natural Science Foundation of China (contract No. 22075252).

Conflict of interest

The authors have no conflict of interest to declare.

References

REFERENCES

Bolla, G., and Nangia, A.. 2016. “Pharmaceutical Cocrystals: Walking the Talk.” Chemical Communications 52 (54): 8342–60.CrossRefGoogle Scholar
Clausen, H. F., Chevallier, M. S., Spackman, M. A., and Iversen, B. B.. 2010. “Three New Co-Crystals of Hydroquinone: Crystal Structures and Hirshfeld Surface Analysis of Intermolecular Interactions.” New Journal of Chemistry 34 (2): 193–99.CrossRefGoogle Scholar
D'Ascenzo, L., and Auffinger, P.. 2015. “A Comprehensive Classification and Nomenclature of Carboxyl–Carboxyl (ate) Supramolecular Motifs and Related Catemers: Implications for Biomolecular Systems.” Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials 71 (2): 164–75.CrossRefGoogle ScholarPubMed
Dassault Systèmes. 2021. Materials Studio. V. 2021. BIOVIA. Windows.Google Scholar
Duggirala, N. K., Frericks Schmidt, H. L., Lei, Z., Zaworotko, M. J., Krzyzaniak, J. F., and Arora, K. K.. 2018. “Solid-State Characterization and Relative Formation Enthalpies to Evaluate Stability of Cocrystals of an Antidiabetic Drug.” Molecular Pharmaceutics 15 (5): 1901–08.CrossRefGoogle ScholarPubMed
El-Gizawy, S. A., Osman, M. A., Arafa, M. F., and El Maghraby, G. M.. 2015. “Aerosil as a Novel Co-Crystal Co-Former for Improving the Dissolution Rate of Hydrochlorothiazide.” International Journal of Pharmaceutics 478 (2): 773–78.CrossRefGoogle ScholarPubMed
Emami, S., Siahi-Shadbad, M., Adibkia, K., and Barzegar-Jalali, M.. 2018. “Recent Advances in Improving Oral Drug Bioavailability by Cocrystals.” Bioimpacts 8 (4): 305–20.CrossRefGoogle ScholarPubMed
Ervasti, T., Aaltonen, J., and Ketolainen, J.. 2015. “Theophylline–Nicotinamide Cocrystal Formation in Physical Mixture During Storage.” International Journal of Pharmaceutics 486 (1–2): 121–30.CrossRefGoogle ScholarPubMed
Friscic, T., and Jones, W.. 2009. “Recent Advances in Understanding the Mechanism of Cocrystal Formation via Grinding.” Crystal Growth and Design 9 (3): 1621–37.CrossRefGoogle Scholar
Kang, Y., Gu, J., and Hu, X.. 2017. “Syntheses, Structure Characterization and Dissolution of Two Novel Cocrystals of Febuxostat.” Journal of Molecular Structure 1130: 480–86.CrossRefGoogle Scholar
Lin, S. Y. 2017. “Simultaneous Screening and Detection of Pharmaceutical Co-Crystals by the One-Step DSC–FTIR Microspectroscopic Technique.” Drug Discovery Today 22 (4): 718–28.CrossRefGoogle ScholarPubMed
Newman, A. W., and Byrn, S. R.. 2003. “Solid-State Analysis of the Active Pharmaceutical Ingredient in Drug Products.” Drug Discovery Today 8 (19): 898905.CrossRefGoogle ScholarPubMed
Nikpour, M., Mirzaei, M., Chen, Y. G., Kaju, A. A., and Bakavoli, M.. 2009. “Contribution of Intermolecular Interactions to Constructing Supramolecular Architecture: Synthesis, Structure and Hirshfeld Surface Analysis of a New Hybrid of Polyoxomolybdate and ((1H-Tetrazole-5-yl) Methyl) Morpholine.” Inorganic Chemistry Communications 12 (9): 879–82.CrossRefGoogle Scholar
Pandey, N. K., Sehal, H. R., Garg, V., Gaur, T., Kumar, B., Singh, S. K., Gulati, M., Gowthamarajan, K., Bawa, P., Rajesh, S. Y., Sharma, P., and Narang, R.. 2017. “Stable Co-Crystals of Glipizide with Enhanced Dissolution Profiles: Preparation and Characterization.” Aaps PharmSciTech 18: 2454–65.CrossRefGoogle ScholarPubMed
Ranjan, S., Devarapalli, R., Kundu, S., Vangala, V. R., Ghosh, A., and Reddy, C. M.. 2017. “Three New Hydrochlorothiazide Cocrystals: Structural Analyses and Solubility Studies.” Journal of Molecular Structure 1133: 405–10.CrossRefGoogle Scholar
Seth, S. K., Saha, N. C., Ghosh, S., and Kar, T.. 2011a. “Structural Elucidation and Electronic Properties of Two Pyrazole Derivatives: A Combined X-Ray, Hirshfeld Surface Analyses and Quantum Mechanical Study.” Chemical Physics Letters 506 (4–6): 309–14.CrossRefGoogle Scholar
Seth, S. K., Maity, G. C., and Kar, T.. 2011b. “Structural Elucidation, Hirshfeld Surface Analysis and Quantum Mechanical Study of Para-Nitro Benzylidene Methyl Arjunolate.” Journal of Molecular Structure 1000 (1–3): 120–26.CrossRefGoogle Scholar
Soman, R., Sujatha, S., and Arunkumar, C.. 2014. “Quantitative Crystal Structure Analysis of Fluorinated Porphyrins.” Journal of Fluorine Chemistry 163: 1622.CrossRefGoogle Scholar
Song, L., Shemchuk, O., Robeyns, K., Braga, D., Grepioni, F., and Leyssens, T.. 2019. “Ionic Cocrystals of Etiracetam and Levetiracetam: The Importance of Chirality for Ionic Cocrystals.” Crystal Growth & Design 19 (4): 2446–54.CrossRefGoogle Scholar
Sopyan, I., Fudholi, A., Muchtaridi, M., and Sari, I. P.. 2017. “Simvastatin-Nicotinamide Co-Crystal: Design, Preparation and Preliminary Characterization.” Tropical Journal of Pharmaceutical Research 16 (2): 297303.CrossRefGoogle Scholar
Spackman, M. A., and Jayatilaka, D.. 2009. “Hirshfeld Surface Analysis.” CrystEngComm 11 (1): 1932.CrossRefGoogle Scholar
Spackman, M. A., and McKinnon, J. J.. 2002. “Fingerprinting Intermolecular Interactions in Molecular Crystals.” CrystEngComm 4 (66): 378–92.CrossRefGoogle Scholar
Spackman, P. R., Turner, M. J., McKinnon, J. J., Wolff, S. K., Grimwood, D. J., Jayatilaka, D., and Spackman, M. A.. 2021. “Crystalexplorer: A Program for Hirshfeld Surface Analysis, Visualization and Quantitative Analysis of Molecular Crystals.” Journal of Applied Crystallography 54 (3): 1006–11.CrossRefGoogle ScholarPubMed
Weijenberg, A., Brouwer, O. F., and Callenbach, P. M.. 2015. “Levetiracetam Monotherapy in Children with Epilepsy: A Systematic Review.” CNS Drugs 29: 371–82.CrossRefGoogle ScholarPubMed
Xu, Y., Jiang, L., and Mei, X.. 2014. “Supramolecular Structures and Physicochemical Properties of Norfloxacin Salts.” Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials 70 (4): 750–60.CrossRefGoogle ScholarPubMed
Yamashita, H., and Sun, C. C.. 2018. “Improving Dissolution Rate of Carbamazepine-Glutaric Acid Cocrystal Through Solubilization by Excess Conformer.” Pharmaceutical Research 35: 17.CrossRefGoogle Scholar
Yoshimura, M., Miyake, M., Kawato, T., Bando, M., Toda, M., Kato, Y., Fukami, T., and Ozeki, T.. 2017. “Impact of the Dissolution Profile of the Cilostazol Cocrystal with Supersaturation on the Oral Bioavailability.” Crystal Growth & Design 17 (2): 550–57.CrossRefGoogle Scholar
Zhang, Y. Q., Li, J., Hu, Y., Tian, Y., and Gao, C. H.. 2010. “The Antiepileptic Drug Levetiracetam.” Chinese Journal of Neuroimmunology and Neurology 17 (2): 145–47.Google Scholar
Figure 0

Figure 1. (a) Levetiracetam molecule containing amine and carbonyl groups; (b) 3,5-dinitrosalicylic acid (abbreviated DNS or DNSA, IUPAC name 2-hydroxy-3,5-dinitrobenzoic acid), an aromatic acid combined with compounds of various structures to form co-crystals; and (c) the LEV-DNS co-crystal prepared by the cooling crystallization method.

Figure 1

Figure 2. FTIR spectra of the levetiracetam (LEV), the 3,5-dinitrosalicylic acid (DNS) and the LEV-DNS co-crystal.

Figure 2

Figure 3. (a) The PXRD patterns of LEV, DNS, and LEV-DNS co-crystal, (b) experimental and simulated XRD patterns of LEV-DNS co-crystal, and (c) Pawley refinement results.

Figure 3

TABLE I. X-ray powder diffraction data of LEV-DNS co-crystal before and after Pawley refinement.

Figure 4

Figure 4. The molecular structures of LEV-DNS co-crystal show the atom-numbering schemes. Displacement ellipsoids are drawn at the 50% probability level. Dashed lines indicate hydrogen bonds.

Figure 5

Figure 5. Interactions occurring in the LEV-DNS co-crystal, the dashed lines represent hydrogen bonds.

Figure 6

TABLE II. Experimental details.

Figure 7

TABLE III. Hydrogen-bond geometry (Å, °) for LEV-DNS co-crystal.

Figure 8

Figure 6. (a) Dihedral angle between LEV molecules and DNS molecules in an asymmetric structural unit and (b) intermolecular interaction diagram of LEV-DNS (along the b-axis).

Figure 9

Figure 7. (a) Hirshfeld surface generated over dnorm, di and de for LEV-DNS co-crystal; (b) shape index; and (c) curvedness mapped over the Hirshfeld analysis.

Figure 10

Figure 8. (a) The 2D fingerprint plot of various intermolecular interaction forces and (b) Pie chart of the relative contribution of various intermolecular interactions on the Hirshfeld surface.

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