Four N⁷-benzyl-substituted 4,5,6,7-tetra­hydro-1H-pyrazolo[3,4-b]pyri­dine-5-spiro-1′-cyclo­hexane-2′,6′-di­ones as ethanol hemisolvates: similar mol­ecular constitutions but different crystal structures

Spiranes are rather rigid structures which are useful as frameworks for the attachment of functional groups incorporating pharmacophoric or metal-coordinating moieties. Spiro skeletons are not only present in numerous naturally occurring alkaloids, but have also been used in drug discovery and in the development of combinatorial libraries (Bazgir et al., 2008). The development of new routes for the synthesis of these frameworks has attracted considerable attention and several distinct approaches have been reported for the preparation of heterocyclic spiranes. These include palladium-promoted spiroannulations onto carbocyclic or heterocyclic substrates (Møller & Undheim, 2003), spirocyclizations mediated by BF₃–Et₂O (Caputo et al., 2003), spiroannulation of carboxylic acids (Rahimizadeh et al., 2007), and oxidative rearrangement sequences and intramolecular Mannich reactions (Marti & Carreira, 2003).

We report here the structures of four closely related compounds, (I)–(IV), all obtained using three-component cyclocondensations induced by microwave irradiation, and all crystallizing as ethanol hemisolvates. We have been investigating such cyclocondensations as part of a programme for the synthesis of fused pyrazolo derivatives (Quiroga et al., 1999), and we have recently reported (Low et al., 2004) the structure of compound (V), obtained from the condensation reaction between 5-amino-3-tert-butyl-1-phenylpyrazole, 5,5-dimethylcyclohexane-1,3-dione (dimedone) and formaldehyde. The constitution of the heterocyclic component in (I)–(IV) differs from that in (V) in having a substituted benzyl group at position N7, rather than an H atom. Compounds (I)–(IV) were synthesized using a straightforward modification of the synthetic method employed earlier, but employing in each case an appropriately-substituted 5-(benzylamino)-3-tert-butyl-1-phenylpyrazole as the amino component (see scheme).

Compounds (I)–(IV) (Fig. 1) all crystallize as stoichiometric ethanol hemisolvates, with the ethanol disordered across a twofold rotation axis in (I)–(III) and across a centre of inversion in (IV). Compounds (I)–(III) are isomorphous in space group C2/c, while (IV) crystallizes in space group P1 with very different unit-cell dimensions. Examination of the refined structures using PLATON (Spek, 2003) showed that artificial removal of the ethanol component from the structures gave rise to four voids per unit cell in (I)–(III), with volumes ranging from 72 ų per void in (I) to 66 ų per void in (II) and (III), amounting in total to ca 5% of the unit-cell volume, and located near (1/2, 2/3, 3/4) and the symmetry-related equivalent positions. In (IV), a similar investigation found a single void centred at (1/2, 1/2, 1.0) and accounting for ca 6.3% of the unit-cell volume. It is possible that the structural role of the ethanol is simply to occupy otherwise void space; this is certainly consistent with its very limited participation in the supramolecular aggregation in the structures of (I)–(IV).

Thus, in each of the two distinct structures, the half-occupancy ethanol component is linked to the heterocyclic component by a combination of a C—H···O hydrogen bond and an O—H···π(arene) hydrogen bond in which the aryl ring of the benzyl substituent acts as the acceptor (Table 2). Statistically, the pairs of heterocyclic molecules related by a twofold axis in (I)–(III) or by inversion in (IV) are each associated with a disordered ethanol molecule lying across the symmetry element in question. However, at the local level, each ethanol site is occupied by a single molecule with a definite orientation, although the two alternative orientations occur with equal probability. Thus, for each ethanol location, one set of atomic sites is fully occupied while the other is vacant. Hence, a specific ethanol molecule is either linked to the heterocycle at (x, y, z) or to its symmetry-relayed companion, but it cannot be linked to two such heterocycles. Thus, the ethanol component plays no further role in the supramolecular aggregation.

The isomorphism of (I)–(III) may be compared with the isomorphous series (VI)–(VIII) (Portilla et al., 2005). On the other hand, in the closely-related 7-aryl-benzo[h]pyrazolo[3,4-b]quinolines, the 4-chlorophenyl and 4-methylphenyl derivatives are isomorphous, while in the isomeric 11-aryl-benzo[f]pyrazolo[3,4-b]quinolines, the corresponding derivatives are not isomorphous (Portilla et al., 2008), although the 4-chlorophenyl compound is isomorphous with the 4-bromophenyl derivative (Serrano et al., 2005a,b).

In each of (I)–(IV), the reduced pyridine ring adopts a half-chair conformation, as shown by the ring-puckering parameters (Table 1; Cremer & Pople, 1975). 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 similarity between the corresponding parameters is very high for the isomorphous compounds (I)–(III), while the parameters for (IV) differ slightly.

The rest of the molecular conformation is determined by the orientation of the three pendent substituents relative to the heterocyclic molecular core, and these orientations can be defined in terms of just six torsion angles (Table 1). The tert-butyl substituent is always slightly rotated about the C3—C31 bond so that atom C33 lies just out of the plane of the pyrazole ring. As with the ring-puckering angles for the pyridine ring, the corresponding torsion angles in the isomorphous compounds (I)–(III) are all very similar, while the out-of-plane rotation of the tert-butyl group is significantly larger in (IV). The observed conformations, together with the pyramidal coordination at atom N7, mean that the molecules have no internal symmetry and hence that they are chiral, although the space group in all cases accommodates a racemic mixture of enantiomers.

The supramolecular aggregation depends upon hydrogen-bond formation between the heterocyclic molecules, and the ethanol components are simply pendent from the resulting hydrogen-bonded aggregates. The aggregation is dominated by hydrogen bonds of C—H···π type, augmented in the case of (IV) by a C—H···O hydrogen bond (Table 2). Of the short intermolecular contacts indicated by PLATON (Spek, 2003) as possible hydrogen bonds, we have discounted all those involving methyl C—H bonds as potential donors. Not only are methyl C—H bonds expected to be of rather low acidity but, in general, methyl groups CH₃—E undergo extremely fast rotation about the C—E bond even in the solid state, as shown by solid-state NMR spectroscopy (Riddell & Rogerson, 1996, 1997). Such contacts of C—H···O type occur in (I)–(III). In each case, however, the fast rotation of the methyl groups about the C—C bonds will render such contacts structurally insignificant. In addition, we have discarded intermolecular C—H···O contacts in which the H···O distance exceeds 2.50 Å, and all contacts where the D—H···A angle is less than 125°. Finally, we have excluded from consideration the intermolecular C—H···Cl and C—H···Br contacts in (I) and (II), as it has been concluded that such contacts involving covalently bound Cl or Br are probably no more than van der Waals contacts, and that geometrically they are certainly at the outer limit of what could conceivably be described as a hydrogen bond (Aakeröy et al., 1999; Brammer et al., 2001; Thallapally & Nangia, 2001).

In compounds (I)–(III) a single C—H···π interaction (Table 2) links pairs of pyrazolopyridine units into a centrosymmetric dimer (Fig. 2), but there are no direction-specific interactions between these dimers, so that the supramolecular structure can be regarded as finite or zero-dimensional.

By contrast, in compound (IV), where an entirely equivalent dimer is formed by paired C—H···π interactions, these dimeric units are further linked by a C—H..O hydrogen bond (Table 2) into a chain of centrosymmetric rings running parallel to the [010] direction (Fig. 3). Rings of R²₂(14) type (Bernstein et al., 1995) formed by pairs of C—H···O hydrogen bonds are centred at (1/2, n, 1/2), where n represents an integer, while the rings formed by pairs of C—H···π interactions are centred at (1/2, 0.5 + n, 1/2), where n represents an integer. There are no direction-specific interactions between these chains of rings, so that the supramolecular structure is one-dimensional.

Compounds (I)–(IV) are thus similar in constitution and their heterocyclic components are very similar in both configuration and conformation. Despite these close resemblances, the range of direction-specific intermolecular interactions and the crystal structures differ between those of the isomorphous compounds (I)–(III) on the one hand and compound (IV) on the other. The contrast between compounds (III) and (IV) is particularly striking, as their compositions differ only in the formal replacement of a CH₃ group in (III) by a CF₃ group in (IV), and as neither of these substituents plays any direct role in the supramolecular aggregation. The prediction of the crystal structures of molecular compounds remains an extremely difficult undertaking which has so far met with very limited success (Day et al., 2005). Any attempts at the present time to explain the structural differences found here between compounds (III) and (IV) are thus likely to be largely speculative.