Four N⁷-alkoxy­benzyl-substituted 4,5,6,7-tetra­hydro-1H-pyrazolo[3,4-b]pyridine-5-spiro-1'-cyclo­hexane-2',6'-diones: hydrogen-bonded supra­molecular structures in zero, one, two or three dimensions

In continuation of our structural study of N⁷-benzyl-substituted pyrazolo[3,4-b]pyridine-5-spiro-1'-cyclohexane-2',6'-diones (Cruz et al., 2008) – itself part of a programme exploring the use of multicomponent condensation reactions, especially those induced by microwave irradiation under solvent-free conditions, for the synthesis of novel heterocycles – we now report the molecular and supramolecular structures of four N⁷-(alkoxybenzyl) derivatives, (I)–(IV) (Figs. 1–4). Compounds (I)–(IV) were synthesized using the reaction between a substituted N-benzylaminopyrazole, 5,5-dimethylcyclohexane-1,3-dione (dimedone) and excess paraformaldehyde, under solvent-free conditions, in a straightforward modification of the synthetic method employed by Cruz et al. (2008).

Compounds (I)–(III) crystallized in solvent-free form, but compound (IV) was found to be a partial ethanol solvate, with 0.67 molecules of ethanol per molecule of the pyrazolopyridine in the crystal selected for data collection. We have not investigated systematically the stoichiometry of this solvate or related solvates, but it is entirely possible that the ethanol content may vary somewhat from one crystal to another. Examination using PLATON (Spek, 2003) of the refined structure of (IV), but with the ethanol component omitted, found eight voids, each of volume ca 96 ų and together accounting for some 12.2% of the unit-cell volume. It is possible that the ethanol of solvation is present in this strucutre merely as a placeholder component, occupying what would otherwise be empty space.

In each compound the reduced pyridine ring adopts a half-chair conformation, as shown (Table 1) by the ring-puckering parameters (Cremer & Pople, 1975), defined here for the atom-sequence (N7, C6, C5, C4, C3A, C7A). For an idealized half-chair ring with equal bond lengths throughout, the ring-puckering angles are θ = 50.8° and ϕ = (60k + 30)°, where k represents an integer.

The rest of the molecular conformation is determined by the orientation of the three pendent substituents relative to the heterocyclic molecular core, and by the orientation of the alkoxy substituents relative to the adjacent aryl ring (Table 1). As indicated by the relevant torsion angles (Table 1), while the orientation of the phenyl and benzyl units relative to the molecular core is fairly similar in each compound, there is considerable variation in the degree to which the tert-butyl group has been rotated about the C3—C31 bond. Since the rotational barrier about this bond approximates to a sixfold barrier, as found when a fragment of local C₃ symmetry, such as a tert-butyl group, is bonded to a fragment with effective local C₂ symmetry, such as a planar ring, it can be expected that the barrier is exceptionally low, no more than a few tens of joules per mole (Tannenbaum et al., 1956; Naylor & Wilson, 1957), so accounting for the variation in the relative orientation of the tert-butyl group.

The orientations of the methoxy substituents in (I), (II) and (IV) show some interesting variations. As shown by the relevant torsion angles (Table 1), the single methoxy group in (I), that at C73 in (II), and those at C73 and C75 in (IV) are all almost coplanar with the adjacent aryl rings. The deviations from the mean planes of these rings are 0.235 (3) Å for atom C741 in (I), 0.006 (3) Å for atom C731 in (II), and 0.147 (5) Å and 0.164 (5) Å for atoms C731 and C751, respectively, in (IV). Associated with each of these effectively in-plane methoxy groups is a marked difference between the two exocyclic C—C—O angles, typically almost 10°. By contrast, the C74/O74/C741 plane in compound (IV) is almost orthogonal to the adjacent ring, with atom C741 displaced by 1.058 (5) Å from the ring plane, while atom C721 in compound (II) is displaced from the adjacent ring plane by 0.944 (3) Å. At the same time, in compound (IV) the exocyclic C—C—O angles at atom C74 are identical within experimental uncertainty, and those at atom C72 in compound (II) differ by less than 3°. Although the in-plane conformation appears to be the most favoured and of lowest energy, maximizing the orbital overlap between the π orbitals of the ring and formally non-bonding 2p orbital on the O atom, this orientation is nonetheless rather easily disrupted by non-bonded (steric) interactions between adjacent substituents. In (III), the five-membered ring formed by the methylenedioxo unit adopts an envelope conformation, folded across the line O71···O72.

Although compounds (I)–(IV) all contain potential hydrogen-bond acceptors – in the methoxy groups in (I), (II) and (IV), and in the methylenedioxo unit in (III) – in no case do these O atoms play any significant role in the supramolecular aggregation. There is a rather long C—H···O contact involving such an O atom in (III) (Table 2), although this is possibly only of marginal structural significance, at best, while the methoxy O atoms in the other three compounds do not form even weak contacts of this type. The principal intermolecular interactions in this series are of C—H···π type and of C—H···O type utilizing carbonyl O atoms as the hydrogen-bond acceptors. There are no π–π stacking interactions in any of (I)–(IV). The partial-occupancy ethanol component in (IV) is connected to the heterocyclic component by a three-point linkage (Table 2), but it plays no role in the supramolecular aggregation, acting simply as a pendent group.

In compound (I), pairs of molecules are linked by the cooperative action of C—H···O and C—H···π hydrogen bonds into centrosymmetric dimers, within which the paired C—H···O hydrogen bonds define an R²₂(22) (Bernstein et al., 1995) motif (Fig. 5), but there are no direction-specific interactions between these dimers; hence the supramolecular aggregation in compound (I) can be regarded as finite, or zero-dimensional.

A single C—H···O hydrogen bond links molecules of (II), which are related by the 2₁ screw axis along (1/2, y, 3/4), into a simple C(11) chain running parallel to the [010] direction (Fig. 6). Two chains of this type related to one another by inversion pass through each unit cell, but there are no direction-specific interactions between adjacent chains.

In (III), a combination of a C—H···O hydrogen bond, with C15 as the donor, and a C—H···π hydrogen bond link the molecules into a chain of centrosymmetric edge-fused rings running parallel to the [100] direction (Fig. 7). Within this chain, R²₂(22) rings exactly analogous to those observed in compound (I) are centred at (n, 1/2, 1/2), where n represents an integer, and these alternate with rings formed by pairs of C—H···π hydrogen bonds, centred at (n + 1/2, 1/2, 1/2), where n represents zero or an integer. Within the structure of (III) there are two further C—H···O contacts, both rather long, and it is of interest to examine their possible structural effects. The interaction involving C13 as the donor links the chains of rings, which are related by translation along [010], while that involving C72 as the donor links the R²₂(22) rings into a chain along [001]. Thus, if these two interactions are regarded as structurally significant, the supramolecular structure based on the one-dimensional chains of rings along [100] (Fig. 7) become successively linked into two-dimensional and three-dimensional arrays.

The heterocyclic components in (IV) are linked into a sheet by two C—H···O hydrogen bonds, both utilizing the same carbonyl acceptor atom, and the formation of the sheet is readily analysed in terms of the individual actions of the two hydrogen bonds. The aryl atom C13 at (x, y, z) acts as a hydrogen-bond donor to the carbonyl atom O51 at (-x, -1/2 + y, 1/2 - z), so linking molecules related by the 2₁ screw axis along (0, y, 1/4), and so forming a C(11) chain running parallel to the [010] direction. In the second substructure, the methylene atom C77 at (x, y, z) acts as a hydrogen-bond donor to atom O51 at (1/2 - x, -1/2 + y, z), thus linking molecules related by the b-glide plane at x = 1/4 into a C(7) chain, again running parallel to the [010] direction. The combination of these two chain motifs generates a sheet of R³₄(28) rings lying parallel to (001) (Fig. 8) and occupying the domain 0 < z < 0.5. A second sheet, related to the first by inversion, occupies the domain 0.5 < z < 1.0, but there are no direction-specific interactions between adjacent sheets. As noted above, the partial-occupancy ethanol molecules are pendent from this sheet, but they play no role in its formation.

Although the methoxy substituents in compounds (I), (II) and (IV) play no direct role in the supramolecular aggregation, it is striking that, as the degree of methoxy substitution increases, so too does the dimensionality of the hydrogen-bonded structure, from zero-dimensional in the monomethoxy compound (I), to one-dimensional in the dimethoxy compound (II) to two-dimensional in the trimethoxy compound (IV). It is interesting to note that the variations in the molecular constitution occur solely in the substituted benzyl ring, which is, of course, remote from the main hydrogen-bond acceptor sites, the carbonyl O atoms and the main hydrogen-bond donor sites, most of which are provided by the unsubstituted phenyl ring.