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The crystal structures of the monoclinic and triclinic poly­morphs of zoledronic acid, C5H10N2O7P2, have been established from laboratory powder X-ray diffraction data. The mol­ecules in both polymorphs are described as zwitterions, namely 1-(2-hy­droxy-2-phosphon­ato-2-phosphono­ethyl)-1H-imidazol-3-ium. Strong inter­molecular hydrogen bonds (with donor–acceptor distances of 2.60 Å or less) link the mol­ecules into layers, parallel to the (100) plane in the monoclinic polymorph and to the (1\overline{1}0) plane in the triclinic polymorph. The phospho­nic acid groups form the inner side of each layer, while the imidazolium groups lie to the outside of the layer, protruding in opposite directions. In both polymorphs, layers related by translation along [100] inter­act through weak hydrogen bonds (with donor–acceptor distances greater than 2.70 Å), forming three-dimensional layered structures. In the monoclinic polymorph, there are hydrogen-bonded centrosymmetric dimers linked by four strong O—H...O hydrogen bonds, which are not present in the triclinic polymorph.

Supporting information

cif

Crystallographic Information File (CIF) https://doi.org/10.1107/S0108270113003089/bi3053sup1.cif
Contains datablocks IM, IT, global

rtv

Rietveld powder data file (CIF format) https://doi.org/10.1107/S0108270113003089/bi3053IMsup2.rtv
Contains datablock IM

rtv

Rietveld powder data file (CIF format) https://doi.org/10.1107/S0108270113003089/bi3053ITsup3.rtv
Contains datablock IT

cml

Chemical Markup Language (CML) file https://doi.org/10.1107/S0108270113003089/bi3053IMsup4.cml
Supplementary material

cml

Chemical Markup Language (CML) file https://doi.org/10.1107/S0108270113003089/bi3053ITsup5.cml
Supplementary material

CCDC references: 934565; 934566

Comment top

Zoledronic acid belongs to the class of bisphosphonic acids, which are excellent therapeutic agents for the treatment of a number of diseases characterized by abnormal calcium metabolism. In particular, zoledronic acid acts as a bone `shield' incorporated into the skeleton, attaining therapeutic concentrations and thus inhibiting bone resorption by cellular effects on osteoclasts. Zoledronic acid has also been shown to be effective in the treatment of early-stage breast cancer (Gnant, 2012) and castration-resistant prostate cancer (Marech et al., 2012). Several polymorphs of zoledronic acid and zoledronate sodium salts and their hydrates have been described by Aronhime & Lifshitz-Liron (2009). However, a search for the crystal structure of zoledronic acid in the Cambridge Structural Database (CSD, Version 5.33 with updates; Allen, 2002) gave no hits. Herewith, we present the crystal structures of its monoclinic, (IM), and triclinic, (IT), polymorphs determined from laboratory X-ray powder diffraction data.

The molecular conformations in (IM) and (IT) are closely comparable (Fig. 1), differing only in the opposite orientation of the imidazole ring. Although the laboratory powder pattern does not allow localization of the O- and N-bound H atoms reliably, one can estimate their most probable positions based on analysis of short intermolecular contacts. Particularly, in (IM) and (IT), intermolecular H···H distances not shorter than 2 Å can be attained only by assuming that the molecules in both forms are zwitterions, namely 1-(2-hydroxy-2-phosphonato-2-phosphonoethyl)-1H-imidazol-3-ium. Thus, all H atoms were geometrically positioned to form zwitterions, and we discuss the hydrogen-bonding patterns in (IM) and (IT) (Tables 1 and 2) on this basis.

Following the idea of strong and weak hydrogen bonds (Desiraju & Steiner, 1999), we define here a strong hydrogen bond as an interaction with a donor–acceptor distance (D···A in Tables 1 and 2) of 2.60 Å or less. For a weak hydrogen bond, this distance is more than 2.70 Å. Using these definitions, we can describe the general features of the hydrogen-bonding patterns that are common for (IM) and (IT). In both crystal structures, strong intermolecular hydrogen bonds (O—H···O) are generated by the phosphonic acid groups. They link the molecules into layers in such a way that the phosphonic acid groups form the central part of each layer, while the imidazolium groups are at the outside of the layer, protruding in opposite directions. These layers are parallel to the (100) plane in (IM) (Fig. 2) and to the (110) plane in (IT) (Fig. 3). Layers related by translation along [100] interact through weak N—H···O and O—H···O hydrogen bonds in (IM) (Table 1) and through weak N—H···O hydrogen bonds only in (IT) (Table 2) to form three-dimensional layered structures.

For both forms, the main difference in hydrogen-bonding motifs is found within the layers. In the layers of (IM), centrosymmetric dimers linked by four strong O—H···O hydrogen bonds are observed (Fig. 2). These dimers are not present in (IT) (Fig. 3). The CSD contains seven single-crystal structures of bisphosphonates with analogous dimers linked by four strong O—H···O hydrogen bonds, with O···O distances less than 2.60 Å, namely, 10-{[(2,2-bisphosphonoethyl)hydroxyphosphoryl]methyl}-1,4,7,10-tetraazacyclododecane-1,4,7-triacetic acid hydrate (Vitha et al., 2009), 1-hydroxy-1-phosphono-3-(1-piperidinio)propyl-1-phosphonate (Fernández & Vega, 2003), pyridinium trihydrogen benzyldiphosphonate and p-xylylenediammonium pentahydrogen 1,4-phenylenebis(methylidyne)tetraphosphonate sesquihydrate (Plabst et al., 2009), bis[tris(1,10-phenanthroline-κ2N,N')nickel(II)] bis[1-hydroxyethane-1-(phosphonic acid)-1-phosphonate] bis(1-hydroxyethane-1,1-diphosphonate) tetrahydrate (Sergienko et al., 2000), 2,2'-bipyridinium hydrogen 1-aminopropane-1,1,3-triphosphonate dihydrate (Wu et al., 2007), and {phosphono[(pyridin-1-ium-3-yl)amino]methyl}phosphonate monohydrate (Matczak-Jon & Ślepokura, 2011). In spite of the presence of such strongly bonded dimers in (IM), its packing with ρ = 1.80 Mg m-3 is less dense than the packing of (IT) with ρ = 1.90 Mg m-3.

Related literature top

For related literature, see: Ahtee et al. (1989); Allen (2002); Aronhime & Lifshitz-Liron (2009); Desiraju & Steiner (1999); Dollase (1986); Fernández & Vega (2003); Gnant (2012); Järvinen (1993); Kieczykowski et al. (1995); Marech et al. (2012); Matczak-Jon & Ślepokura (2011); Pawley (1981); Plabst et al. (2009); Popa (1998); Ruscica et al. (2010); Sergienko et al. (2000); Sridhar & Ravikumar (2011); Toraya (1986); Visser (1969); Vitha et al. (2009); Werner et al. (1985); Wu et al. (2007); Zhukov et al. (2001); Zlokazov (1992, 1995); Zlokazov & Chernyshev (1992).

Experimental top

Zoledronic acid monosodium salt was prepared according to a known procedure (Kieczykowski et al., 1995). The crude product (30 g) was suspended in distilled water (450 ml) and the pH was adjusted to 1.5 with concentrated HCl. The suspension was heated to 363 K with stirring and complete dissolution occurred after 15 min at this temperature. The solution was then cooled to 283 K with stirring and a precipitate of zoledronic acid formed slowly. After overnight incubation at 278 K, the precipitate was filtered off, washed with methanol and placed in a flask fitted with a Dean–Stark trap. To obtain (IM), benzene (80 ml) was added and the reaction mixture was boiled for 2 h. To obtain (IT), toluene (80 ml) was added and the reaction mixture was boiled for 4 h (isolation of water ended after 1 h). The product was cooled, filtered and dried in vacuo (1 mbar; 1 bar = 100000 Pa) at 323 K. For (IM), 11.2 g of zoledronic acid was recovered as a white crystalline powder. For (IT), 10.5 g of zoledronic acid was recovered as a white crystalline powder.

Refinement top

X-ray powder diffraction data for (IM) were collected using a Panalytical EMPYREAN instrument with a linear X'celerator detector using nonmonochromated Cu Kα radiation. Data for (IT) were collected using a Huber G670 Guinier camera with an imaging-plate detector using monochromated Cu Kα1. The latter instrument was used for (IT) in order to minimize strong texture effects observed in the pattern measured with the EMPYREAN instrument. The unit-cell dimensions were determined using three indexing programs: TREOR90 (Werner et al., 1985), ITO (Visser, 1969) and AUTOX (Zlokazov, 1992, 1995). Based on systematic extinctions, the space group for (IM) was determined as P21/c, whereas the space group of (IT) was assumed to be P1. The unit-cell parameters and space groups were further tested using a Pawley fit (Pawley, 1981) and confirmed by the successful crystal structure solution and refinement. The powder pattern of (IM) contains three weak peaks (d spacings = 4.886, 3.552 and 3.345 Å) that are assumed to arise from another polymorphic form of zoledronic acid.

The structures were solved using a simulated annealing technique (Zhukov et al., 2001). The geometry of the anion (without H atoms) from the crystal structure of cytosimium zoledronate trihydrate (Sridhar & Ravikumar, 2011) was used as the initial molecular model. In the simulated annealing runs, six external and four internal degrees of freedom were varied.

The solutions found were fitted with the program MRIA (Zlokazov & Chernyshev, 1992) in the bond-restrained Rietveld refinement using a split-type pseudo-Voigt peak-profile function (Toraya, 1986). In the refinement of (IM), anisotropic line-broadening was taken into account with the use of nine variables (Popa, 1998), and symmetrized harmonics expansion up to the sixth order (Ahtee et al., 1989; Järvinen, 1993) was used for correction of the texture effect (the minimum and maximum texture multipliers for the calculated intensities were 0.61 and 1.22, respectively). In the refinement of (IT), the March–Dollase (Dollase, 1986) formalism was used for correction of preferred orientation in the direction [011] (the minimum and maximum texture multipliers for the calculated intensities were 0.96 and 1.01, respectively). Restraints were applied to the intramolecular bond lengths and contacts (<2.8 Å). The geometric parameters for the restraints were taken from the crystal structure of zoledronic acid trihydrate (Ruscica et al., 2010) and the strength of the restraints was a function of interatomic separation and corresponded to an r.m.s. deviation of 0.02 Å for intramolecular bond lengths. Additional restraints were applied to the planarity of the imidazole ring with attached atom C2, with the maximum allowed deviation from the mean plane being 0.02 Å. All non-H atoms were refined isotropically. H atoms were positioned geometrically (C—H = 0.93 or 0.97 Å, O—H = 0.82 Å and N—H = 0.86 Å) and not refined. The diffraction profiles for both compounds after the final bond-restrained Rietveld refinements are shown in Fig. 4.

Computing details top

Data collection: DataCollector (PANalytical, 2010) for (IM); Software for G670 Imaging-Plate Guinier Camera (Huber, 2002) for (IT). For both compounds, cell refinement: MRIA (Zlokazov & Chernyshev, 1992). Data reduction: DataCollector (PANalytical, 2010) for (IM); Software for G670 Imaging-Plate Guinier Camera (Huber, 2002) for (IT). For both compounds, program(s) used to solve structure: simulated annealing (Zhukov et al., 2001); program(s) used to refine structure: MRIA (Zlokazov & Chernyshev, 1992); molecular graphics: PLATON (Spek, 2009) and Mercury (Macrae et al., 2008); software used to prepare material for publication: MRIA (Zlokazov & Chernyshev, 1992) and SHELXL97 (Sheldrick, 2008).

Figures top
[Figure 1] Fig. 1. The molecular structure of the zoledronate zwitterion in (IM) (top) and (IT) (bottom), showing the atomic numbering. Displacement ellipsoids are drawn at the 50% probability level.
[Figure 2] Fig. 2. The hydrogen-bonded layer in (IM), viewed along [100] (top) and [010] (bottom). Thin lines (blue in the electronic version of the paper) denote strong O—H···O hydrogen bonds. The centrosymmetric dimers discussed in the text are visible in the top figure. H atoms not involved in hydrogen bonding have been omitted. [Symmetry codes: (i) ?; (ii) ? Please complete]
[Figure 3] Fig. 3. The hydrogen-bonded layer in (IT), viewed approximately along the normal to the layer (top) and along [111] (bottom). Thin lines (blue in the electronic version of the paper) denote strong O—H···O hydrogen bonds. H atoms not involved in hydrogen bonding have been omitted. [Symmetry codes: (i) ?; (ii) ?; (iii) ? Please complete]
[Figure 4] Fig. 4. The final Rietveld plots for (IM) (top) and (IT) (bottom). The experimental diffraction profiles are indicated by black dots. The calculated diffraction profiles are shown as the upper solid lines (red in the electronic version of the paper), the difference profiles are shown as the bottom solid lines (blue) and the vertical bars (green) correspond to the positions of the Bragg peaks.
(IM) 1-(2-Hydroxy-2-phosphonato-2-phosphonoethyl)-1H-imidazol-3-ium top
Crystal data top
C5H10N2O7P2F(000) = 560
Mr = 272.09Dx = 1.805 Mg m3
Monoclinic, P21/cMelting point: 503 K
Hall symbol: -P 2ybcCu Kα radiation, λ = 1.5418 Å
a = 6.8162 (12) ÅT = 298 K
b = 10.6307 (11) ÅParticle morphology: plate
c = 13.9240 (14) Åwhite
β = 96.954 (18)°flat sheet, 15 × 1 mm
V = 1001.5 (2) Å3Specimen preparation: Prepared at 298 K and 101 kPa
Z = 4
Data collection top
PANanalytical EMPYREAN
diffractometer
Data collection mode: reflection
Radiation source: line-focus sealed tubeScan method: continuous
None monochromator2θmin = 7.009°, 2θmax = 79.973°, 2θstep = 0.017°
Specimen mounting: thin layer on the non-diffracting silicon plate
Refinement top
Refinement on InetProfile function: split-type pseudo-Voigt (Toraya, 1986)
Least-squares matrix: full with fixed elements per cycle121 parameters
Rp = 0.03343 restraints
Rwp = 0.0480 constraints
Rexp = 0.030H-atom parameters not refined
RBragg = 0.061Weighting scheme based on measured s.u.'s
χ2 = 2.570(Δ/σ)max = 0.002
4293 data pointsBackground function: Chebyshev polynomial up to the fifth order
Excluded region(s): nonePreferred orientation correction: spherical harmonics expansion up to the sixth order (Ahtee et al., 1989; Järvinen, 1993)
Crystal data top
C5H10N2O7P2β = 96.954 (18)°
Mr = 272.09V = 1001.5 (2) Å3
Monoclinic, P21/cZ = 4
a = 6.8162 (12) ÅCu Kα radiation, λ = 1.5418 Å
b = 10.6307 (11) ÅT = 298 K
c = 13.9240 (14) Åflat sheet, 15 × 1 mm
Data collection top
PANanalytical EMPYREAN
diffractometer
Scan method: continuous
Specimen mounting: thin layer on the non-diffracting silicon plate2θmin = 7.009°, 2θmax = 79.973°, 2θstep = 0.017°
Data collection mode: reflection
Refinement top
Rp = 0.0334293 data points
Rwp = 0.048121 parameters
Rexp = 0.03043 restraints
RBragg = 0.061H-atom parameters not refined
χ2 = 2.570
Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
P10.4912 (5)0.2154 (3)0.4136 (3)0.0551 (14)*
P20.3277 (5)0.0379 (3)0.3270 (3)0.0542 (15)*
O10.4207 (10)0.1527 (6)0.2262 (6)0.076 (3)*
H10.38110.21920.20110.114*
O20.6808 (12)0.1419 (7)0.4400 (6)0.077 (3)*
O30.3630 (10)0.2083 (7)0.4980 (6)0.070 (3)*
H30.42860.17860.54590.104*
O40.5183 (10)0.3460 (6)0.3771 (5)0.063 (3)*
O50.1945 (11)0.0584 (6)0.4078 (6)0.072 (3)*
H50.26000.08950.45530.108*
O60.5327 (10)0.0958 (7)0.3482 (6)0.073 (3)*
O70.2373 (10)0.0873 (6)0.2264 (5)0.066 (3)*
H70.32240.08790.18960.099*
N10.0030 (13)0.1423 (9)0.2245 (7)0.068 (4)*
N20.2341 (14)0.0293 (8)0.1485 (7)0.071 (4)*
H20.32890.02400.13650.084*
C10.3363 (15)0.1350 (11)0.3146 (9)0.064 (5)*
C20.1328 (16)0.2003 (11)0.3027 (9)0.068 (5)*
H2A0.07540.19480.36300.082*
H2B0.14960.28860.28820.082*
C30.1481 (16)0.0617 (11)0.2363 (9)0.077 (5)*
H3A0.18300.03320.29510.093*
C40.1468 (16)0.0945 (11)0.0809 (8)0.065 (5)*
H40.18480.09360.01440.080*
C50.0051 (16)0.1610 (10)0.1276 (9)0.074 (5)*
H5A0.09650.20950.09970.090*
Geometric parameters (Å, º) top
P1—O41.498 (7)N1—C31.333 (15)
P1—O21.516 (9)N1—C51.370 (16)
P1—O31.549 (9)N1—C21.476 (14)
P1—C11.842 (12)N2—C31.336 (15)
P2—O51.544 (9)N2—C41.362 (15)
P2—O61.522 (8)N2—H20.86
P2—O71.552 (8)C1—C21.542 (15)
P2—C11.847 (12)C2—H2A0.97
O1—C11.434 (15)C2—H2B0.97
O1—H10.82C3—H3A0.93
O3—H30.82C4—C51.354 (15)
O5—H50.82C4—H40.93
O7—H70.82C5—H5A0.93
O4—P1—O2115.0 (5)O1—C1—C2107.3 (9)
O4—P1—O3114.0 (4)O1—C1—P1109.2 (7)
O2—P1—O3109.5 (5)C2—C1—P1107.4 (8)
O4—P1—C1105.0 (5)O1—C1—P2103.4 (7)
O2—P1—C1109.7 (5)C2—C1—P2114.8 (8)
O3—P1—C1102.7 (5)P1—C1—P2114.4 (6)
O5—P2—O6114.1 (5)N1—C2—C1111.5 (9)
O5—P2—O7114.0 (4)N1—C2—H2A109.3
O6—P2—O7107.0 (4)C1—C2—H2A109.3
O5—P2—C1103.6 (5)N1—C2—H2B109.3
O6—P2—C1112.4 (5)C1—C2—H2B109.4
O7—P2—C1105.4 (5)H2A—C2—H2B107.9
C1—O1—H1109.5N1—C3—N2107.6 (11)
P1—O3—H3109.5N1—C3—H3A126.2
P2—O5—H5109.5N2—C3—H3A126.2
P2—O7—H7109.4C5—C4—N2107.8 (10)
C3—N1—C5109.5 (9)C5—C4—H4126.0
C3—N1—C2125.8 (10)N2—C4—H4126.1
C5—N1—C2124.7 (9)C4—C5—N1106.1 (10)
C3—N2—C4108.7 (9)C4—C5—H5A126.9
C3—N2—H2125.6N1—C5—H5A127.0
C4—N2—H2125.7
Hydrogen-bond geometry (Å, º) top
D—H···AD—HH···AD···AD—H···A
O3—H3···O6i0.821.712.481 (11)156
O5—H5···O2i0.821.572.359 (11)160
O7—H7···O4ii0.821.672.436 (10)156
N2—H2···O4iii0.861.882.740 (11)172
O1—H1···O6iv0.822.192.899 (11)145
Symmetry codes: (i) x+1, y, z+1; (ii) x+1, y1/2, z+1/2; (iii) x, y1/2, z+1/2; (iv) x+1, y+1/2, z+1/2.
(IT) 1-(2-Hydroxy-2-phosphonato-2-phosphonoethyl)-1H-imidazol-3-ium top
Crystal data top
C5H10N2O7P2Z = 2
Mr = 272.09F(000) = 280
Triclinic, P1Dx = 1.901 Mg m3
Hall symbol: -P 1Melting point: 495 K
a = 8.4217 (13) ÅCu Kα1 radiation, λ = 1.5406 Å
b = 8.6039 (11) ŵ = 4.50 mm1
c = 8.1818 (12) ÅT = 298 K
α = 92.778 (16)°Particle morphology: no specific habit
β = 112.415 (17)°white
γ = 116.072 (19)°flat sheet, 15 × 1 mm
V = 475.33 (12) Å3Specimen preparation: Prepared at 298 K and 101 kPa
Data collection top
Huber Guinier Camera G670
diffractometer
Data collection mode: transmission
Radiation source: line-focus sealed tubeScan method: continuous
Curved Germanium(111) monochromator2θmin = 7.00°, 2θmax = 80.00°, 2θstep = 0.01°
Specimen mounting: thin layer in the specimen holder of the camera
Refinement top
Refinement on InetProfile function: split-type pseudo-Voigt (Toraya, 1986)
Least-squares matrix: full with fixed elements per cycle102 parameters
Rp = 0.02643 restraints
Rwp = 0.0330 constraints
Rexp = 0.015H-atom parameters not refined
RBragg = 0.050Weighting scheme based on measured s.u.'s
χ2 = 4.550(Δ/σ)max = 0.002
7301 data pointsBackground function: Chebyshev polynomial up to the fifth order
Excluded region(s): nonePreferred orientation correction: March–Dollase (Dollase, 1986) texture correction
Crystal data top
C5H10N2O7P2γ = 116.072 (19)°
Mr = 272.09V = 475.33 (12) Å3
Triclinic, P1Z = 2
a = 8.4217 (13) ÅCu Kα1 radiation, λ = 1.5406 Å
b = 8.6039 (11) ŵ = 4.50 mm1
c = 8.1818 (12) ÅT = 298 K
α = 92.778 (16)°flat sheet, 15 × 1 mm
β = 112.415 (17)°
Data collection top
Huber Guinier Camera G670
diffractometer
Scan method: continuous
Specimen mounting: thin layer in the specimen holder of the camera2θmin = 7.00°, 2θmax = 80.00°, 2θstep = 0.01°
Data collection mode: transmission
Refinement top
Rp = 0.0267301 data points
Rwp = 0.033102 parameters
Rexp = 0.01543 restraints
RBragg = 0.050H-atom parameters not refined
χ2 = 4.550
Special details top

Geometry. All esds (except the esd in the dihedral angle between two l.s. planes) are estimated using the full covariance matrix. The cell esds are taken into account individually in the estimation of esds in distances, angles and torsion angles; correlations between esds in cell parameters are only used when they are defined by crystal symmetry. An approximate (isotropic) treatment of cell esds is used for estimating esds involving l.s. planes.

Fractional atomic coordinates and isotropic or equivalent isotropic displacement parameters (Å2) top
xyzUiso*/Ueq
P10.2088 (4)0.6438 (4)0.4230 (4)0.0380 (15)*
P20.1622 (4)0.7888 (4)0.0929 (5)0.0431 (15)*
O10.1430 (9)0.4938 (9)0.1814 (10)0.050 (3)*
H10.06740.46380.24980.075*
O20.1274 (10)0.5710 (10)0.5770 (10)0.057 (3)*
O30.1769 (9)0.8325 (9)0.4878 (9)0.055 (3)*
H30.09350.87750.59520.083*
O40.4320 (8)0.5176 (9)0.2965 (9)0.047 (3)*
H40.44620.46330.20230.071*
O50.3872 (9)0.7015 (8)0.0065 (9)0.052 (3)*
O60.0680 (9)0.9850 (9)0.1807 (10)0.051 (3)*
O70.0814 (9)0.7559 (9)0.0395 (10)0.053 (3)*
H70.04880.84150.08370.080*
N10.2623 (11)0.8163 (11)0.3117 (12)0.068 (4)*
N20.4221 (11)0.8120 (11)0.1616 (12)0.058 (4)*
H20.46720.77470.09990.070*
C10.0909 (16)0.6710 (15)0.2673 (16)0.067 (5)*
C20.1331 (14)0.7658 (15)0.4031 (15)0.064 (5)*
H2A0.16700.87280.48490.077*
H2B0.15780.68650.47680.077*
C30.3042 (16)0.7112 (15)0.2292 (15)0.062 (5)*
H3A0.25880.58970.22100.074*
C40.4610 (14)0.9836 (14)0.2045 (16)0.063 (5)*
H4A0.54621.08160.17950.076*
C50.3532 (15)0.9854 (16)0.2901 (16)0.058 (5)*
H50.34231.08260.32740.070*
Geometric parameters (Å, º) top
P1—O21.498 (9)N1—C31.34 (2)
P1—O41.548 (6)N1—C51.372 (15)
P1—O31.554 (9)N1—C21.472 (18)
P1—C11.858 (16)N2—C31.324 (16)
P2—O61.505 (8)N2—C41.359 (16)
P2—O51.527 (7)N2—H20.86
P2—O71.555 (11)C1—C21.556 (14)
P2—C11.856 (14)C2—H2A0.97
O1—C11.443 (16)C2—H2B0.97
O1—H10.82C3—H3A0.93
O3—H30.82C4—C51.35 (2)
O4—H40.82C4—H4A0.93
O7—H70.82C5—H50.93
O2—P1—O4112.7 (4)O1—C1—C2106.3 (11)
O2—P1—O3113.6 (4)O1—C1—P2110.9 (8)
O4—P1—O3108.2 (5)C2—C1—P2115.3 (8)
O2—P1—C1112.5 (6)O1—C1—P1106.9 (8)
O4—P1—C1104.3 (5)C2—C1—P1102.6 (8)
O3—P1—C1104.9 (5)P2—C1—P1114.1 (9)
O6—P2—O5111.2 (5)N1—C2—C1113.4 (10)
O6—P2—O7112.2 (5)N1—C2—H2A108.9
O5—P2—O7110.4 (4)C1—C2—H2A108.9
O6—P2—C1110.5 (5)N1—C2—H2B108.8
O5—P2—C1109.6 (5)C1—C2—H2B108.8
O7—P2—C1102.6 (6)H2A—C2—H2B107.8
C1—O1—H1109.5N2—C3—N1107.5 (11)
P1—O3—H3109.5N2—C3—H3A126.4
P1—O4—H4109.5N1—C3—H3A126.2
P2—O7—H7109.5C5—C4—N2107.3 (10)
C3—N1—C5108.6 (11)C5—C4—H4A126.3
C3—N1—C2128.2 (10)N2—C4—H4A126.4
C5—N1—C2123.1 (12)C4—C5—N1106.9 (12)
C3—N2—C4109.6 (12)C4—C5—H5126.6
C3—N2—H2125.2N1—C5—H5126.5
C4—N2—H2125.2
Hydrogen-bond geometry (Å, º) top
D—H···AD—HH···AD···AD—H···A
O4—H4···O5i0.821.692.406 (9)144
O7—H7···O6ii0.821.802.604 (10)166
O3—H3···O6iii0.821.762.559 (10)166
O1—H1···O2iv0.821.872.682 (12)172
N2—H2···O5v0.862.022.877 (13)171
Symmetry codes: (i) x1, y+1, z; (ii) x, y+2, z; (iii) x, y+2, z+1; (iv) x, y+1, z+1; (v) x+1, y, z.

Experimental details

(IM)(IT)
Crystal data
Chemical formulaC5H10N2O7P2C5H10N2O7P2
Mr272.09272.09
Crystal system, space groupMonoclinic, P21/cTriclinic, P1
Temperature (K)298298
a, b, c (Å)6.8162 (12), 10.6307 (11), 13.9240 (14)8.4217 (13), 8.6039 (11), 8.1818 (12)
α, β, γ (°)90, 96.954 (18), 9092.778 (16), 112.415 (17), 116.072 (19)
V3)1001.5 (2)475.33 (12)
Z42
Radiation typeCu Kα, λ = 1.5418 ÅCu Kα1, λ = 1.5406 Å
µ (mm1)4.50
Specimen shape, size (mm)Flat sheet, 15 × 1Flat sheet, 15 × 1
Data collection
DiffractometerPANanalytical EMPYREAN
diffractometer
Huber Guinier Camera G670
diffractometer
Specimen mountingThin layer on the non-diffracting silicon plateThin layer in the specimen holder of the camera
Data collection modeReflectionTransmission
Scan methodContinuousContinuous
2θ values (°)2θmin = 7.009 2θmax = 79.973 2θstep = 0.0172θmin = 7.00 2θmax = 80.00 2θstep = 0.01
Refinement
R factors and goodness of fitRp = 0.033, Rwp = 0.048, Rexp = 0.030, RBragg = 0.061, χ2 = 2.570Rp = 0.026, Rwp = 0.033, Rexp = 0.015, RBragg = 0.050, χ2 = 4.550
No. of data points42937301
No. of parameters121102
No. of restraints4343
H-atom treatmentH-atom parameters not refinedH-atom parameters not refined

Computer programs: DataCollector (PANalytical, 2010), Software for G670 Imaging-Plate Guinier Camera (Huber, 2002), simulated annealing (Zhukov et al., 2001), PLATON (Spek, 2009) and Mercury (Macrae et al., 2008), MRIA (Zlokazov & Chernyshev, 1992) and SHELXL97 (Sheldrick, 2008).

Hydrogen-bond geometry (Å, º) for (IM) top
D—H···AD—HH···AD···AD—H···A
O3—H3···O6i0.821.712.481 (11)156
O5—H5···O2i0.821.572.359 (11)160
O7—H7···O4ii0.821.672.436 (10)156
N2—H2···O4iii0.861.882.740 (11)172
O1—H1···O6iv0.822.192.899 (11)145
Symmetry codes: (i) x+1, y, z+1; (ii) x+1, y1/2, z+1/2; (iii) x, y1/2, z+1/2; (iv) x+1, y+1/2, z+1/2.
Hydrogen-bond geometry (Å, º) for (IT) top
D—H···AD—HH···AD···AD—H···A
O4—H4···O5i0.821.692.406 (9)144
O7—H7···O6ii0.821.802.604 (10)166
O3—H3···O6iii0.821.762.559 (10)166
O1—H1···O2iv0.821.872.682 (12)172
N2—H2···O5v0.862.022.877 (13)171
Symmetry codes: (i) x1, y+1, z; (ii) x, y+2, z; (iii) x, y+2, z+1; (iv) x, y+1, z+1; (v) x+1, y, z.
 

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